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=“ggjj)msmpif\. SOCIOECONOFAICWUD{ES PW3GRAM
Technical ReportNumber 49
Alaska OCSSocioeconomicStudies Program
‘ Sponsor-
Bureau ofLand Management
— Alaska Outer
Bering-Nor~onPetroleum DeveloprnenI Scenarios
The United States Department of the Interior was designated by the OuterContinental Shelf (OCS) Lands Act of 1953 to carry out the majority ofthe Act’s provisions for administering the mineral leasing and develop-ment of offshore areas of the United States under federal jurisdiction.Within the Department, the Bureau of Land Management (BLM) has theresponsibility to meet requirements of the National Environmental PolicyAct of 1969 (lJRPA] as well as other legislation and regulations dealingwith the effects of offshore development. In Alaska, unique culturaldifferences and climatic conditions create a need for developing addi-tional socioeconomic and environmental information to improve OCS deci-sion making at all governmental levels. In fulfillment of its federalresponsibilities and with an awareness of these additional informationneeds, the BI14 has initiated several investigative programs, one ofwhich is the Alaska OCS Socioeconomic Studies Program (SESP).
The Alaska OCS Socioeconomic Studies Program is a multi-year researcheffort which attempts to predict and evaluate the effects of Alaska OCSPetroleum Development upon the physical, social, and economic environ-ments within the state. The overall methodology is divided into threebroad research components. The first component identifies an alterna-
tive set of assumptions regarding the location, the nature, and thetiming of future petroleum events and related activities. In thiscomponent, the program takes into account the particular needs of thepetroleum industry and projects the human, technological, economic, andenvironmental offshore and onshore development requirements of theregional petroleum industry.
The second component focuses on data gathering that identifies thosequantifiable and qualifiable facts by which OCS-induced changes can beassessed. The critical community and regional components are identifiedand evaluated. Current endogenous and exogenous sources of change andfunctional organization among different sectors of community and region-al life are analyzed. Susceptible community relationships, values,activities, and processes also are included.
The third research component focuses on an evaluation of the changesthat could occur due to the potential oil and gas development. Impactevaluation concentrates on an analysis of the impacts at the statewide,regional, and local level.
In general, program products are sequentially arranged in accordancewith BLM’s proposed OCS “lease sale schedule, so that information istimely to decisionmaking. Reports are available through the NationalTechnical Information Service, and the BLM has a limited number ofcopies available through the Alaska OCS Office. Inquiries for informa-tion should be directed to: Program Coordinator (COAR), SocioeconomicStudies Program, Alaska OCS Office, P. 0. Box 1159, Anchorage, Alaska99510.
Technical Report No. 49
ALASKA OCS SOCIOECONOMIC STUDIES PROGRAMNORTON BASIN
O&S LEASE SALE NO. 57PETROLEUM DEVELOPMENT SCENARIOS
FINAL REPORT
Prepared for
BUREAU OF LAND MANAGEMENTALASKA OUTER CONTINENTAL SHELF OFFICE
BY
Peter T. HanleyWilliam W. WadeGordon S.HarrisonDouglas F. Jones
Prepared by
DAMES& MOORE
January 1980
)Contract No. AA550-CT6-61Task 9CG
,
Job No. 8699-019-20
III
NOTICES
1. This document is disseminated under the sponsorship of the U.S.Department of the Interior, Bureau of Land Management, in theinterest of information exchange. The U.S. Government assumes noliability for its content or use thereof.
2. This final report is designed to provide preliminary petroleumdevelopment data to the groups working on the Alaska OCS Socio-economic Studies Program~ The assumptions used to generate off-shore petroleum development scenarios may be subject tu revision.
3. The units presented in this report are metric with American equiva-lents except units used in standard petroleum practice. Theseinclude barrels (42 gallons, oil), cubic feet (gas), pipelinediameters {inches), well casing diameters (inches), and well spacing(acres).
ALASKA OCS SOCIOECONOMIC STUDIES PROGRAMNorton BasinOCS Lease Sale No, 57Petroleum Development ScenariosFinal Report
Technical Report No. 49
Prepared by
DAMES & MOORE
January 1980
9
TABLE OF CONTENTS
List of Tables
List of Figures
1.0 INTRODUCTION
1.1 Purpose. . . ● ~ . ● .* : D ● . ● t“ ● ● ● ● ● ● ““ “ ● ● *
1.2 Scope. . . . . . ● ● . ● 9 ● +“” ● ● ● ● ● ?“ ● ● ● ● ● ● ●
1.3 Data Gaps and Limitations . . . . . . . . . . . . . . . . . . .
1.4 Report Content and Format . . . . . . . . . . . . . . . . . . .
2.1
2.2
2.3
2.4
2.5
3.1
3.2
2.0 SUMMARY
Petroleum Geology and Resource
Selected Petroleum Development
Estimates
Scenarios
2.2.1 Exploration Only Scenario . . . .2.2.2 High Find Scenario . . . . . . . .2.2.3 Medium Find Scenario . . . . . . .2.2.4 LOW
Employment
Technology
Find Scenario . . . . . . . .
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and Production Systems . . . .
Economics . . . . . . . . . . .
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3.0 METHODOLOGY AND ANALYTICAL ASSIJ~PTIONS
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✎Introduction . . . . . . . . . . . . . ● ● ● ● ● ● ●
Petroleum Geology, Reservoir, and Production Assumptions
3.2.13.2.2
3.2.3
Introduction. . . . . . . . . . . . . . .Summary of Norton Basin Petroleum Geology
3.2.2.1 Regional Framework . . . . . . .3.2.2.2 Structure . . . . . . . . . . . .3.2.2.3 Source Rocks . . . . . . . . . .3.2.2.4 Reservoir Roe@ . . . . . . . . .3.2.2.5 Traps. . . . . . . . . . . . . .
U.S. Geological Survey Resource Estimates
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3.2.4 Assumptions . . . . . . . . . . . . . . . . . . . . . . .
3.2.4.1 Initial Production Rate . . . . . . . . . . . .
Oil . . . . . . . . . . . . .0 . . . . . . . . . .Non-AssociatedGas . . . . . . . . . . . . . . . . .
3.2.4.2 Reservoir Depth . . . . . . . . . . . . . + . .3.2.4.3 Recoverable Reserves . . . . . . . . . . . . .
Technical Discussion3.2.4.4 Well Spacing . . . . . . . . . . . . . . . . .
General Considerations and Oil . . . . . . . . . . .Non-AssociatedGas . . . . . . . . . . . . . . . . .
3.2.4.5 Field Sizes and Field Distribution . . . . . .3.2.4.6 Allocation of the U.S. Geological Survey
Gas Resource Estimate Between Associatedand Non-Associated and Gas-Oil Ratio (GOR) . .
3.2.4.7 Oil Properties . . . . . . . . . . . . . . , .
3.3 Technology and Production System Selection . . . . . . . . . .
3.4 Summary of Field Development Cases for Economic Evaluation . .
3.5 Economic Analysis . . . . . . . . . . . . . . . . . . . . . . .
3.5.1 Role of the Economic Analysis in Scenario Formulation .3.5.2 The Objective of the EconomicAnalysis . . . . . . . . .3.5.3 The Model and the Solution Process . . . . . . . . . . .
3.5.3.1 Thehlodel . . . . . . . . . .“. . . . . . . . .3.5.3.2 Solution . . . . . . . . . . . . . . . . . . .
3.5.4 The Assumptions . . . . . . . . . . . . . . . . . . . -
3.5.4.1 ValueofMoney. . . . . . . . . . . . . . . .3.5.4.2 Inflation. . . . . . . . . . . . . . . . . . .3.5.4.3 Oil Prices . . . . . . . . . . . . . . . . . i
World Market. . . . . . . . . . . . . . . . . . . .TheLinktoAlaska. . . . . . . . . . . . . . . . .Norton Basin Crude Well-Head Value . . . . . . . . .
3.5.4.4 Gas Prices . . . . . . . . . . . . . . . . . .3.5.4.5 Effective. . . . . . . . . . . . . . . . . . *3.5.4.6 Tax Credits Depreciation and Depletion . . . .3.5.4.7 Fraction of Investment as Intangible Costs . .3.5.4.8 Investment Schedules . . . . . . . . . . . . .3.5.4.9 Operating Costs . . . . . . . . . . . . . . . .
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4.0 SCENARIO DEVELOPMENT
4.1 Identification of Skeletal Scenarios and Selection ofDetailed Scenarios . . . . . . . . . . . . . . . . . . . . . . .79
4.1.10 il Scenarios . . . . . . . . . . . . . . . . . . ...94
High Find Maximum Onshore Impact (Table 4-1) . . . . 94High Find Minimum Onshore Impact (Table 4-2) . . . . !l~Medium Find Maximum Onshore Impact (Table 4-3) . . .Medium Find Minimum Onshore Impact (Table 4-4) . . . 95Low Find Maximum Onshore Impact (Table 4-5) . . . . 95Low Find Minimum Onshore Impact (Table 4-6) . , . . 95
4.1.2 Non-Associated Gas Scenarios (Tables 4-7, 4-8,,and4-9) . . . . . . . . . . . . . . . . . . . . . . . . 96
4.1.3 Exploration Only.... . . . . . . . . . . . . . . . . 964.1.4 Scenarios Selected for Detailing . . . . . . . . . . . . 96
Oil . . . . . . . . . . . . . . . . . . . . . ...96Non-AssociatedGas . . . . . . . . . . . . . . . . . 97Exploration Only. . . . . . . . . . . . . . . . , . 97
4.2 Detailing of Scenarios . . . . . . . . . . . . . . . . . . . . 97
4.2.1 Introduction . . . . . . . . . . . . . . . . . . . . . . 974.2.2 The LocationofFields . . . . . . . . . . . . . . . . . 984.2.3 Exploration and Field Discovery Schedules . . . . . . .4.2.4 Major Facilities and Their Siting . . . . . . . . . . . 1%4.2.5 Field Development and Operation Scheduling . . . . . . . 1004.2.6 Translation of Field Development and Operation
Schedules Into Employment Estimates . . . . . . . . . . 100
5.0 EXPLORATION ONLY SCENARIO
5.1 General Description. . . . . . . . . . . . . . . . . . . . . . 103
5.2 Tracts and Location . . . . . . . . . . . . . . . . . . . . . . 103
5.3 Exploration Schedule.. . . . . . . . . . . . . . . . . . . . 103
5.4 Facility Requirements and Locations . . . . . . . . . . . . . . 103
5.5 Manpower Requirements . . . . . . . . . . . . . . . . . . . . . 105
5.6 Environmental Considerations . . . . . . . . . . . . . , . . . . 105
VII
TABLE OF CONTENTS (~Ot’lt.)
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6.1
6.2
6.3
6.4
6.5
6.6
7.1
7.2
7.3
7.4
7.5
7.6
8.1
8.2
8.3
8.4
8.5
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6.0 HIGH FIND
General Description . . . . . . .
Tracts and Location . . . . . . .
SCENARIO
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General Description .
Tracts and Location .
MEDIUM FIND SCENARIO
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8.0 LOW FIND
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SCENARIO
General Description . . . . . . . . . . .
Tracts and Location . , . . . . . . . . .
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Exploration, Development, and Production Schedules
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TABLE OF CONTENTS (Cont.]
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APPENDIX A -THE ECONOMICS OF FIELD DEVELOPMENT IN THE NORTON BASIN
I. Introduction. . . . . . . . . . . . . . . . . . . . . . . . . . A-1
1.1 Oil . . . . . . . ..~. . . . . . . . . . . . . . . . . . . . A-1
1.2 Gas. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . A-2
11. Analytical Results . . . . . . . . . . . . . . . . . . . . . ..A-3
11.1 Minimum Field Size to Justify Development . . . . . . . . . . A-3
11.1.1 Oil . . . . . . . . . . . . . . . . . . . . . . . . . . A-3
11.1.1.1 Effect of Reservoir Target Depth on Oi~Field Development Economics . . . . . . . . . . . A-3
11.1.1.2 Effect of Water Depth on Oil FieldDevelopment Economics . . . . . . . . . . . . . A-7
11.1.1.3 The Effect of Initial Well Production Rateson Oil Field Development Economics . . . . . . . A-7
11.1.1.4 The Effect of Pipeline Distance to Shoreon Oil Field Development Economics . . . . . . . A-II
11.1.1.5 Effect of Delay on Oil Field DevelopmentEconomics . .; . . . . . . . . . . . . . . . . A-n
11.1.1.6 The Effects of Other Production Systems onOil Field Development Economics . . . . . . . . A-15
Two Platforms. . . . . . . . . . . . . . . . . . . . A-15Gravel Islands. . . . . . . . . . . . . . . . . . . A-17Offshore Loading . . . . . . . . . . . . . . . . . ..A-17
11.1.2 Non-Associated Gas . . . . . . . . . . . . . . . . . . A-17
11.1.2.1 Effect of Reservoir Target Depth on GasField Development Economics. . . . . . . . . . . A-19
11.1.2.2 Effect of Initial Production Rates onGas Field Development Economics . . . . . . . . A-19
11.1.2.3 Effect of Offshore Pipeline Distance toShore on Gas Field Development Economics . . . . A-20
11.2 Minimum Required Price to Justify Field Development . . . . . A-20
11.2.1 Oil . . . . . . . . . . . . . . . . . . . . . . . . . . A-2211.2.2 Non-Associated Gas . . . . . . . . . . . . . . . . . . A-22
11.3 Distribution of Oil Development Costs Between OffshoreProduction, Pipeline Transport, and Shore Terminal . . . . . . A-25
VIX
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TABLE OF CONTENTS (Cont.)
PacJg11.4 The Effect of the Uncertainty of Estimated Costs and
Prices on Field Development Economics . . . . . . . . - . . . A-25
IF.4.1 Sensitivity Analysis for Single Steel PlatformOil Field Development.. . . . . . . . . . . . . . ..A-25
11.4.2 Monte Carlo Results for Selectd ProductionScenarios. . . . . . . . . . . . . . . . . . . . .0 . A-28
11.4.2.1 Range of Values for After Tax Returnon Investment . . . .“. . . . . . . . . . . . . A-28
11.4.2.2 Oil Platforms . . . . . . . . . . . . . . . . . A-2911.4.2.3 Gas Platforms . . . . . . . . . . . . . . . . . A-29
APPENDIX B -
PETROLEUM DEVELOPMENT COSTS AND FIELD DEVELOPMENT SCHEDULES
I. Data Base . . . . . . . . . . . . . . . . . . . . . . . . . B-1
II.. Published Database. . . . . . . . . . . . . . . . . . . . . B-2
111. Cost and Field Development Schedule Uncertainties . . . . . . B-3
111.1 Platform Fabrication and Installation (Tables B-1 and B-2) . 8-13
111.2 Platform Process Equipment (Tables B-3A and B-3B) . . . . . . B-14
111.3 Marine Pipeline Cost Estimates (Table B-5A) . . . . . . . . . B-14
111.4 Onshore Pipelines (Table B=-5B} . . . . . . . . e . . . . . . B-15
111.5 Oil Terminal Costs (Table B-6) . . . . . . . . . . . . . . . B-16
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n?. Methodology. . . . . . . . . . . . . . . . . . . . . . . . . B-16.*
v. Exploration and Field Development Schedules . . . . . . . . . B-IT
V.1 Potential Problems with Norton Basin Exploration andField Construction Schedules . . . . . . . . . . . . . . . . B-23
VI. Scheduling Assumptions . . . . . . . . . . . . . ; . 0 . . . B-26
APPENDIX C - PETROLEUM TECHNOLOGY AND PRODUCTION.
10 Offshore Arctic Petroleum Experience . . . . . . . . . . . . C-2
l.l Canadian BeaufortSea ..”.. . . . . . . . . . . ...00 .C-2
x
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TABLE OF CONTENTS (Cont.) Pag_e
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Alaskan Beaufort Sea . .
Canadian Arctic Islands .
Eastern Canadian Arctic .
Environmental Constraints
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to Petroleum Development
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11.1.1 Introduction11.1.2 Bathymetry .11.1.3 Circulation .11.1.4 Ice . . . . .11.1.5 Tides . . . .11.1.6 waves and Storm Surge11.1.7 Oceanographic Comparisons with Upper Cook
and Implications for Platform DesignInlet
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Geology and Geologic’ Hazards . . . . .
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11.2.1 Tectonic Setting11.2.2 Regional Geology11.2.3 Surficial Geology11.2.4 Geologic Hazards
11.2.4.1 Tectonism
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11.2.4.2 Soil Instability . . .11.2.4.3 Erosion and Deposition
Biology . . . . . . . . . . . . . .
CoastalTerrestrial-Wetland Habitats of11.3.111.3.2
the. .
. .
ZoneMarine and Estuarine Systems .
Seabirds . . . . . . . . . .
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Intertidal and Shallow Benthos .Fishes. . . . . . . . . .Marine Mammals . . . . . .
Subsistence and Sport HuntingBiological Constraints on OCSEnvironmental Regulations . .
Resources . . . . . . . . . .
Introduction . . . . . . . .
. . .
. . .
11.3.311.3.411.3.5
11.4 Gravel
11.4.111.4.2
and Fishing .Petroleum Development● ☛☛
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~o~ton SoundDistribution of Gravel Resources in
XI
oTABLE OF CONTENTS (Cont.)
11.4.2.1 Coastal Plain at Nome . . .11.4.2.2 Offshore Zone at Nome . . .11.4.2.3 North of St.. Lawrence Island
11.4.3 Availability of Gravel for Offshore11.4.4 Conclusions . . . . . . .
11.5 Water Resources . . . . . . . .
11.5.1 Water Resources Inventory
11.5.1.1 Surface Mater11.5.1.2 Ground Water .
11.5.2 Water Use . . . . . .
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111. Drilling Platforms . . . . . . . . . . .
111,1 Artificial Islands . . . . . . . . . .
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111.1.1 Design and Construction Techniques111.1.2 Construction Materials . . . . . .111.1.3 Ice Action on Islands . . . . . .
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111.1.5 Membrane Contained Island (HydrostaticallySupported Sand Island) . . . . . .
111.2 Ballasted Barges . . . . . . . . . . . .
111.3 Reinforced Ice Platforms . . . . . . . .
111.3.1 Artificial Ice Island . . . . . .111.3.2 Reinforced Floating Ice Platform .
111.4 Ice-Strengthened Drillships . . . . . . .
111.4.1 Drilling Program and Problems111.4.2 Applica~ion to Norton Sound
111.5 Ice-Resistant Structures . . . . . . .
111.5.1 Monopod . . . . . . . . . . . .111.5.2 Cone. . . . . . , . . . . . . .111.5.3 Monotone . . . . . . ~ . . . . .111.5.4 Upper Cook Inlet Type Platforms
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~
C-59C-59c-61C-62C-63
C-63
C-63
C-63c-66
c-68
c-68C-=72C-73
c-75
C-76
C-77C-81C-83
C-=85
c-88
C-90
C-91
C-=91C-94
C-95
c-97C-99
C-99
c-99C-lolC==I03C-106
‘@
XII
TABLE OF CONTENTS (Cont.)
Page
C-106
C-107
C-108
C-109
C-no
111.6 Other Platforms .
Pipelines . . . .
Offshore Loading
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Application of Offshore Loading Scund
Production System Selection for Economic Analysis
APPENDIX D - PETROLEUM
Introduction . . . . . . . .
Previous Studies . . . . . .
Facility Siting Requirements
Temporary Service Base . . .
Permanent Service Base . . .
FACILITIES SITING
D-1
D-2
D-5
D-5
D-5
D-7
D-7
D-8
1.
11.
111.
111.1
111.2
111.3
111.4
111.5
Iv.
IV.I
IV.2
IV.3
IV.4
IV*5
IV.6
IV.7
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Construct
Marine Oi”
Liquefied
Potential
on Support Base . .
Terminal . . . . .
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.Natural Gas Plants
Shore Facility Sites in Norton BasinLease Sale Area
General . . . .
Nome . . . . .
Cape Nome . . .
Cape Darby . .
Northeast Cape
Lost River . .
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The Role of an Aleutian Island Support Basin inNorton Basin Petrleum Development . . . . . . . D-14
XIII
TABLE OF CONTENTS (Cont.) o
IV.8
111.1
111.2
111.3
111.4
111.5
Iv.
IV.1
v.
VI.
VII.
Results. . . . . . . . . . .
APPENDIX E -
. . . . . .
EMPLOYMENT
Expense of Labor in the Arctic
Labor Saving Techniques . . . .
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Prefabricated, Barge-t40unted LNG Plant
Labor Intensive Arctic Construction . .
Construction of Artificial Islands . .
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Manpower Estimates
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Affecting Labor Utilization
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Definitions . . . . . . . . . . . . .
Job . . . . . . . . . . . .Crew . . . . . . . . . . . .Estimated Shift Labor ForceShift . . . . . . .Rotation Factor . .Total Employment . .On-Site Employment .Off-site EmploymentMan+lonths . . . . .
The OCS Manpower Model . . .
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☛Description of Model and Assumptions
APPENDIX F - THE MARKETING OF NORTON BASIN OIL AND GAS
The Marketing of Norton Basin Oil and Gas . , , . . . . .
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D-16
E-4
E-5
E-6
E-7
E-7
E-11
E-12
E-13
E-13E-13E-=14E-14E-14E-14E-=14E-14E-=15
E-16
E-18
F-l
00
XIV
Table
2-1
2-2
2-3
2-4
2-5
2-6
2-7
2-8
2-9
2-10
2-11
2-12
3==1
3-2
3-3
3-4
3-5
3-6
)3-7
LIST OF TABLES
P a g e
Exploration Only Scenario - Low Interest Lease Sale . . .
HighFindOil Scenario . . . . . . . . . . . . . . . . . .
High Find Non-Associated Gas Scenario. . . . . . . . . . .
Medium FindOi~ Scenario . . . . . . . . . . . . . . . . .
Medium Find Non-Associated Gas Scenario . . . . . . . . . .
Low FindOil Scenario . . . . . . . . . . . . . . . . . .
Low Find Non-Associated Gas Scenario . . . . . . . . . . .
Summary of Manpower Requirements for All Industries -Exploration Only Scenario - Onsite and Total . . . . . . .
Summary of Manpower Requirements for All Industries -High Find Scenario - Onsite and Total . . . . . . . . . .
Summary of Manpower Requirements for All Industries -Medium Find Scenario - Onsite and Total . . . . . . . . .
Summary of Manpower Requirements for All Industries -Low Find Scenario - Onsite and Total . . . . . . . . . . .
Representative Pipeline Distances to Nearest TerminalSite Evaluated in Economic Analysis . . . . . . . . . . .
Maximum Area which can be Reached with De~iatedWells Drilled from a Single Platform . . . . . . . . . . .
Representative Pipeline Distances to NearestTerminal Site Evaluated in Economic Analysis . . . . . . .
Summary of Reservoir Characteristics Evaluatedin the Economic,Analysis . . . . . . . . . . . . . . . . .
Production Platforms and Water Depths Evaluatedin the Economic Analysis . . . . . . . . . . . . . . . . ●
U.S. Average Oil and Gas Price and ProductionCost Inflation Since 1974.. . . . . . . . . . . . . . .
Landed Value of Ar;bian and Iranian Light Crudes . . . . .
Value of North Slope Crude on Gulf Coast ReplacingIranian Light, Arabian Light, or Isthmus . . . . . . . . .
10
12
13
15
16
17
18
21
22
23
24
26
49
60
61
62
70
73
75
xv
-- —-- —----- .-. ,LIST UF [ABLES (Cont. ~
Table
4-=1
4-2
4-3
4-4
4-5
4-6
4-7
4-8
4--9
4-10
4-11
5-1
5-2
5-3
5-4
5-5
6-1
6-2
6-3
6-=4
6-5 -
6-6
High Find Oil Maximum Onshore Impact .
High Find Oil Minimum Onshore Impact .
Medium Find Oil Maximum Onshore Impact
Medium Find Oil Minimum Onshore Impact
LOW Find Oil Maximum Onshore Impact .
Low Find Oil Minimum Onshore Impact .
High Find Non-Associated Gas Scenario
. . . . . . e...
.****. .0..
. . . ..s ❑ 0..
..*.** . . . .
. ...0. ● . . .
,,
. ...’. . . . *
Medium Find Non-Associated Gas Scenario . . . . . . . . .
Low Find Non-Associated Gas Scenario . . . . . . . . . . .
High Interest Lease Sale . . . . . . . . . . . . . . . . .
Low Interest Lease Sale... . .,........0-.
Exploration Only Scenario - Low Interest Lease Sale . . .
Onsite Manpower Requirements by Industry -Exploration Only Scenario . . . . . . . . . . . . . . g ~
January, July, and Peak Manpower Requirements -Exploration Only Scenario . . . . . . . . . . . . . . 0 e
Yearly Manpower Requirements by Activity -Exploration Only Scenario . * . . . . . . . . . . . . . .
Summary of Manpower Requirements for All Industries -Exploration Only Scenario - Onsite and Total . . . . . ● .
High Find Oil Scenario . . . . . . . . . . . . . . . . . .
High Find Non-Associated Gas Scenario . . . . . . . . . .
High Fihd Scenario -Fields and Tracts . . . . . . . . . .
Exploration Schedule for Exploration and Delineationof Wells - High Find Scenario . . . . . . . . . . . . . .9
Timing of Discoveries -High Find Scenario . . . S ~ S ~ ~
Platform Construction and Installation Schedule -High Find Scenario. . . . . . . . . . . . . . . . . . . .
XVI{.-
PacJg’
81
82
83
84
85
86
87
88
89
90
!?1
104
106
107
*
.*
108
e
*
LIST OF TABLES
PageTable
6-7
6-8
6-9
6-10
6-11
6-12
6-13
6-14
6-16
6-17
6-18
7-1
7-2
7-3
7-4
7-=5
7-6
7-7
Development Well Drilling Schedule - High Find Scenario . 120
Exploration and Production Gravel Islands - HighFind Scenario . . . . . . . . . . . . . . . . . . . . . . 121
Pipeline Construction Schedule - High Find Scenario -Kilometers (Miles) Constructed by Year . . . , . . . . . . 122
Major Facilities Construction Schedule - High FindScenario . . . . . . . . . . . . . . . . . . . . . . . . . 123
Field Production Schedule - High Find Scenario . . . . . . 124
High Find Scenario Production by Year for IndividualFieldsandTotal -Oil . . . . . . . . . . . . . . . . . . 125
High Find Scenario Production by Year for IndividualFields and Total - Non-Associated Gas . . . . . . . . . . 126
Major Shore Facilities Start Up and Shut Down Dates -HighFindScenario. . . . . . . . . . . . . . . . . . . . 127
Onsite Manpower Requirements by Industry -HighFindScenario. . . . . . . . . . . . . . . . . . . . 130
January, July, and Peak Manpower Requirements -HighFindScenario. . . . . . . . . . . . . . . . . . . . 131
Yearly Manpower Requirements by Activity -HighFindScenario. . . . . . . . . . . . . . . . . . . . 132
Summary of Manpower Requirements for All Industries -High Find Scenario - Onsite and Total . . . . . . . . . . 135
Medium FindOil Scenario.. . . . . . . . . . . . . . . . 138
Medium Find Non-Associated Gas Scenario . . . . . . . . . 139
Medium Find Scenario - Fields and Tracts . . . . . . . . . 142
Exploration Schedule for Exploration and Delineationof Wells -Medium Find Scenario . . . . . . . . . . . . . 144
Timing of Discoveries - Medium Find Scenario . . . . . . . 145
Platform Construction and Installation Schedule -Medium Find Scenario ..”... . . . . . . . . . . . . . . 146
Development Well Drilling Schedule - Medium FindScenario. . . . . . . . . . . . . . . . . . . . . . . . . 147
LIST OF TABLES (Cent.~
Table
7-8
7-9
7-10
7-11
7-12
7-’13
7=’14
7-15
7-16
7-17
7-=18
8-1
8-2
8-3
8-4
8-5
8-6
8-7
a-8
Page
Exploration and Production Gravel Islands - MediumFind Scenario . . . . . . . ~ . . . . . . .
Pipeline Construction Schedule - Medium FindKilometers (Miles) Constructed by Year . . .
Major Facilities Construction Schedule - Med.$cenario ..e . . . .. o...... . . .
FieJd Production Schedule - Medium Find Sceni
. . ...0 . 148
Scenario -. . . . . . . 149
urn Find. . . . . . . 150
rio. . . . . 151
Medium Find Scenario Production by Year for IndividualFields andTotal -Oil . . . . . . . . . . . . . . . . . .
Medium Find Scenario Production by Year for IndividualFields and Total - Non-Associated Gas . . . . ; . . . . .
Major Shore Facilities Start Up and Shut Down Dates -Medium Find Scenario . . . . , . . . . . . . . . . . . . . .
Onsite Manpower Requirements by Industry -Medium Find Scenario . . . . . , . . . . . . . . . , . . .
January, July, and Peak Manpower Requirements -Medium Find Scenario . . . . . . . . . . . . . . . . . . .
Yearly Manpower Requirements by Activity -Medium Find Scenario . . . . . . . . . . . . . . . . . .
Summary of Manpower Requirements for All Industries -Medium Find Scenario - Onsite and Total . . . . . . . . .
Low FindOil Scenario . . . . . . . . . . . . . . . . . .
Low Find Non-Associated Gas Scenario . . . . . . . . . . .
Low Find Scenario -Fieldsand Tracts . . . . . . . . . .
Exploration Schedule for Exploration and Delineationof Wells - LowFind Scenario . . . . . . . . . . . . . . .
Timing of Discoveries - Low Find Scenario . . ; , . . . .
Platform Construction and Installation Schedule -LowFind Scenario , . . . . . . . . . . . . . . . . . . .
Development Well Drilling Schedule - Low Find Scenario . .
Exploration and Production Gravel Islands - LowFind Scenario . . . . . . . . , . . . . . . . . . ;. . .
\
XVIII
152
153
154
157
158
159
162
164
165
168
171
172
173
LIST OF TABLES (Cont.)
Table
8-9
8-10
8-11
8-12
8-13
8-14
8-15
8“16
8-17
8-18
A-1
A-2
A-3
A-4
A-5
A-6
) A-7
Pipeline Construction Schedule - Low Find Scenario -Kilometers (Miles) Constructed by Year . . . . . . . . . .
Major Facilities Construction Schedule - Low FindScenario . . . . . . . . . . . . . . . . . . . . . . . . .
Field Production Schedule - Low Find Scenario . . . . . .
Low Find Scenario Production by Year for IndividualFields andTotal -Oil.... . . . . . . . . . . . . . .
Low Find Scenario Production by Year for IndividualFields and Total - Non-Associated Gas . . . . . . . . . .
Major Shore Facilities Start Up and Shut Down Dates -LowFindScenario . . . . . . . . . . . . . . . . . . . .
Onsite Manpower Requirements by Industry -LowFindScenario . . . . . . . . . . . . . . . . . . . . .
January, July,. and Peak Manpower Requirements -Low Find Scenario . . . . . . . . . . . . . . . . . . . .
Yearly Manpower Requirements by Activity -LowFindScenario . . . . . . . . . . . . . . . . . . . .
Summary of Manpower Requirements for All Industries -Low Find Scenario - Onsite and Total . . . . . . . . . . .
Maximum Ultimate Recoverable Reserves from a SinglePlatform. . . . . . . . . . . . . . . . . . . . . . , . .
Effect of Reservoir Target Depth on Oil FieldDevelopmentE conomics. . . . . . . . . . . . . . . . . .
Effects of Water Depth on Oil Field DevelopmentEconomics . . . . . . . . . . . . . . . . . . . . . . . .
Effect of Initial Nell Productivity on FieldDevelopment Economics . . . . . . . . . . . . . . . . . .
Effect of Pipeline Distance to Shore on FieldDevelopment Economics . . . . . . . . . . . . . . . . . .
Effect of Ilelay on Oil Field Development Economics . . , .
Effect of Other Production Systems on Oil FieldDevelopment Economics . . . . . . . . . . . . . . . . . .
Vrv
Page
174
175
176
177
178
179
182
183
184
187
A-4
A-6
A-8
A-9
A-12
A-14
A-16
ALA
------ -. -.-— ,-LISI UF TA13LLS (Lent. )
Table
A-8
A-9
A-10
A-n
A-12
B-1
B-2
B-3A
B-3$
B-4
B-5A
B-5B
B-6
B-7
B-8
c-l
C-2
c-3
Effect of Reservoir Conditions on Gas FieldDevelopment Economics . . . . . . . . . . . . . . . . . . A--18
Distribution of Oil Development Costs Between OffshoreProduction, Pipeline Transport, and Terminal . . . . . . . A-26
Sensitivity Analysis for After Tax Rate of Return as aFunction of Upper & Lower Limit Oil Development Costs . . A-27
Single Oil Platform with 32 km Pipeline to Shore,125 Million Barrel Field, 45 mklater Depth, 2,286 mReservoir Target, Initial Production Rate: 2,000 B/D . . . A-30
Single Oil Platform with 32 kmPipeline to Shore,30 mWater Depth, 2,286 m Reservoir Target, InitialProduction Rate: 15 MMCFD . . . . . . . . . . . . . . . . . A-32
Platform Cost Estimates Installed . . . . . . . . . . . . B.-4
Artificial Island Cost Estimates . . . . . . . . . . . . . B-5
Platform Equipment and Facilities Cost EstimatesOil Production . . . . . . . . . . . . . . . . . . . . ..B-6
Platform Equipment and Facilities Cost EstimatesNon-Associated Gas Production . . . . . . . . . . . . . . B-7
Development Well Cost Estimates , . . . . . . . , . . . . B-8
Marine Pipeline Cost Estimates . . . . . . . . . . . . . . B-9
Onshore Pipeline Cost Estimates . . . . . . . . . . . . . B-IO
Oil Terminal Cost Estimates . . . . . . . . . . . . . . . B-II.Annual Field Operating Cost Estimates . . . . . . . . . . B-12
Example of Tables Used in Economic Analysis Case -Single Steel Platform, Pipeline to Shore Terminal,Water Depths 15 to 46 Meters, 2,286 Meter Oil Reservoir . B-18
Major Seabird Colonies ’in the Norton Sound Lease SaleRegion, Based on Colony Censuses in the Period1966 -1976 . . . . . . . . . . . . . . . . . . . . . . .. c-=35
Substrates of the Littoral Zone from Sheldon’s Point(Yukon Delta) to Cape Pri”nce of Wales, Norton SoundRegion. . . . . . . . . . . . . . . . . . . . . . . . . . c-37
PeriodsBays of
of Concentrations of Salmon in Shallow Waterthe Norton Sound Region . . . . . . . . . . , . . C-42
xx
LIST OF TABLES (Cont.)
Table
c-4
c-5
C-6
C-7
C-8
C-9
c-lo
C-n
C-12
C-13
C-14
C-15
D-1
‘E-I
E-la
E-=2
E-3a
E-3b
Summary of Temporal Use of the Norton Sound LeaseSale ’Area by Pinnipeds and Cetaceans . . . . . . . . . . . ‘C-48
Summary of Locations Sensitive to Disruption by OCSPetroleum Development Activities . . . . . . . . . , . . . C-52
Permits and Regulations Concerning PetroleumDevelopment . . . . . . . . . . . . . . . . . . . . . . . C-56
Summary of Gravel Requirements for Various PetroleumFacilities in Arctic and Subarctic Regions . . . . . . . . C-57
Inventory of Surface Waters in the Norton Sound Area . . . C-64
U.S.G.S. Stream Flow Data for Norton Sound Subregion . . . C-67
Water Supplies in Norton Sound Communities . . . . . . . . C-69
Artificial Island Construction Spread . . . . . . . . . . C-82
Artificial Island Specifications and Fill Requirements . . C-84
Specifications and Design Criteria - ArcticProduction Monocone . . . . . . . . . . . . . . . . . . . C-105
Comparison of Design Related OceanographicConditions in Norton Sound and Upper Cook Inlet . . . . . C-111
Summary of Exploration and Production Platform Options . . C-114
Summary of Petroleum Facility Siting Requirements . . . . D-6
OCS Manpower Employment Model . . . . . . . . . . . . . . E-19
Special Manpower Assumptions for Norton Sound . . . . . . E-23
Scale Factors Used to Account,for Influence of FieldSize and Other Conditions on Manpower Requirements . . . . E-25
.Manpower Estimates for Major Onshore Facilities,Summary’ . . . . . . . . . . . . . . . . . . . . . . . . . E-27
Monthly Manpower Loading Estimates, Major OnshoreConstruction Projects . . . . . . . . . . . . . . . . . . E-28
XXI
nn
Table
E-4
E-4a,
E-5
E-6
E-7
E-8
E-=9
E-10
E-11
E-12
E-13
E-14
E-15
E-16
E-17
E-18
.
OCS Manpower
LIST OF TABLES (Cont.)
Page
Employment Model . . . . . . . . . . . . . . E-33
Special Manpower Assumptions for Norton Sound . . . . . . E-37
List of Tasks by Activity .-. . . . . . . . . . . . . . . E-38
High Find Scenario Production by Year forIndividual Fields and Total - Oil . . . . . . . . . . . . E-39
High Find Scenario Production by Year forIndividual Fields and Total - Non-Associated Gas . . . . . E-40
Medium Find Scenario Production by Year farIndividual Fields and Total - Oil . . . . . . . . . . . . . E-41
Medium Find Scenario Production by Year forIndividual Fields and Total Non-Associated Gas . . . . . . E-42
Low Find Scenario Production by Year for”Individual Fie?ds and Total - Oil . . . . . . . . . . . . E-43
Low Find Scenario Production by Year forIndividual fields and Total Non-Associated Gas . . . . . E-44
Field Production Schedule - High Find Scenario , . . . . . E-45
Major Shore Facilities Start Up and Shut DownDates - HighFindScenario . . . . . . . . . . . . . . . “E-46
Field Production Schedule - Medium Find Scenario . . . . E-47
Major Shore Facilities Start Up and ShutDown Dates - Medium Find Scenario . . . . . . . . . . . . E-48
Field Production Schedule - Low Find Scenario . . . . . . E-49
Major Shore Facilities Start Up and Shut DownDates -Low Find Scenario . . . . . . . . . . . . ..”. .E-5O
Onsite”Manpower Requirements by Industry -Exploration Only . . . . . . . .e. .. E~51 . . . ..E~5l
●
●
●
●
LIST OF TABLES (Cont.)
Table
E-19
E-20
E-21
E-22
E-23
E-24
E-25
E-26
E-27
E-28
E-29
E-30
E-31
E-32
E-33
January, July and Peak Manpower Requirements -Exploration Only. . . . . . . . . . . . . . . . . . . . .
Yearly Manpower Requirements by Activity -Exploration Only. . . . . . . . . . . . . . . . . . . . .
Summary of Manpower Requirements for allIndustries -Exploration Only..... . . . . . . . . .
Onsite Manpower Requirements by Industry -HighFindScenario. . . . . . . . . . . . . . . . . . . .
January, July and Peak Manpower Requirements -HighFind Scenario. . . . . . . . . . . . . . . . . . . .
Yearly Manpower Requirements by Activity -High Find Scenario. . . . . . . . . . . . . . . . . . . .
Summary of Manpower Requirements for all Industries -HighFindScenario. . . . . . . . . . . . . . . . . . . .
Onsite Manpower Requirements by Industry -Medium Find Scenario, . . . . . . . . . . . . . . . . . .
January, July and Peak Manpower Requirements -Medium Find Scenario . . . . . . . . . . . . . . . . . . .
Yearly Manpower Requirements by Activity -Medium Find Scenario . . . . . . . . . . . . . . . . . . .
Summary of Manpower Requirements for all Industries -Medium Find Scenario . . . . . . . . . . . . . . . . . . .
Onsite Manpower Requirements by Industry -LowFindScenario . . . . . . . . . . . . . . . . . . . .
January, July and Peak Manpower Requirements -Low Find Scenario . .. fi . . . . . . . . . . . ..OO.
Yearly Manpower Requirements by Activity -LowFindScenario . . . . . . . . . . . . . . . . . . . .
Summary of Manpower Requirements for all Industries -LowFindScenario . . . . . . . . . . . . . . . . . . . ,.
PagEJ
E-52
E-53
E-54
E-55
E-56
E-57
E-59
E-60
E-61
E-62
E-64
E-65
E-66
E-67
E-69
,,.,-.,..
LIST OF FIGURES
Location of the Study Area .
*
. . . . . ● ☛✎✎✎ ✎ ✎ ✎ ✎ ✎ 3
& Moore Petl)oleum ●
. . . . . . .*.*.* *.*. 3 4Logic and Data Flow of DamesDevelopment Scenario Model .
3-2 Logic and Data Flow for Field Development and forDiscount Cash Flow Analysis . . . . . . . . . . . . . . . 35
High Find Scenario, Field and Shore FacilityLocations, Central and Outer Norton .Souhci . . . . . . . . 114
6-1
6-2 High Find Scenario, Field and Shore FacilityLocations, Inner Norton Sound . . . . . . . . . . . . . . 115
Medium Find Scenario, Field and Shore Facility 9Locations, Central and Outer Norton Sound . . . . . . . . 140
7-1
Me~ium Find Scenario, Field and Shore FacilityLocations, Inner Norton Sound . . . . . . . . . . . . . . 141
7-2
Low Find Scenario, Field and Shore Facility mLocations, Central and Outer Sound . . . . . . . . . . . . 166
8-1
8-2 Low Find Scenario, Field and Shore FacilityLocations, Inner Norton Sound . . . . . . . . . . . . . . 167
Effect of Offshore Pipeline Distance on Rate of oReturn, Oil Field . . . . . . . . . , . , . . . . . . . . A-13
A-1
A-2 Effect of Offshore Pipeline Distance on R..ite ofReturn, Gas Field . . . . . . . . . . . . . . . . . . . . A-21
A-3 Minimum Price to Justify Development of an Oil Field: *Offshore Loading Compared with Pipeline to Shore . . . . . A-23
A-4 Minimum Price to Justify Development of a Gas Field;Single Steel P?atform with 16 km Pipeline to Shore . . . . A-24
A-5 Monte Carlo Results for After Tax Rate of Return *Single Oil Platform with 32 Km. Pipeline to Shore125 Million Barrel Reservoir . . . . . . . . . . . . . . . A-31
Monte Carlo Results for After Tax Rate of ReturnSingle Gas Platform with 32 Km. Pipeline to Shore . . . . A-33
A-6
●Example of Medium-Sized Field Completion ScheduleSingle Steel Platfrom, Oil Pipeline to Shore, Shore aTerminal in Non-Ice-Infested Environment . . . . . . . . . 5-1!3
B-1
●
XXIV
LIST OF FIGURES (Cont.)
E@!EB-2
c-l
C-2
C-3
C-4
C-5
C-6
C-7
C-8
C-9
c-lo
C-11
C-12
C-13
C-14
C-15
C-16
C-ii’
C-18
Initial Input
Page
Information . . . . . . . . . . . . . . . . B-20
Arctic Petroleum Frontiers . . . . . . . . . . . . . . . . C-3
Surface Water Circulation Pattern in Summer and Winter . . C-7
Seasonal Ice Conditions in the Bering and Chukchi Seas . . C-12
Breakup and Freezeup Data, Northwest Region . . . . . . . C-13
Ice Gouging in Northeastern Bering Sea . . . . . . . . . . C-14
Tidal Elevations at Selected Locations Mithin andNear ProposedSaleArea . . . . . . . . . . . . . . . . . C-15
Norton Sound Region Major Fault Zones . . . . .’. . . . . C-19
Generalized Geologic Map of the Northern Bering SeaRegion. . . . . . . . . . . . . . , . . . . . . . . . . . C-21
Distribution and Density of Craters on the Sea Floorof Norton Sound - Also shown are isopaths of Holocenemud (Yukon silt) derived from the Yukon River anddeposited since Holocene, post-glacial sea level rise . . C-26
Potential Geohazards in Norton Sound . . . . . . . . . . . C-29
Vegetation of the Coastal Zone, Seabird Colonies, andLocations of Marine Resource Areas Proposed UnderFLPMA Withdrawals for Inclusion in the NationalWildlife Refuge System... . . . . . . . . . . . . . . . C-31
Diversity Patterns of Benthic Invertebrates andNearshore Fishes . . . . . . . . . . . . . . . . . . . ..c-39
Salmon Fishing Zones and Streams of the Lease Area . . . . C-41
Approximate Extent of Major Mammal Concentrations intheLeaseArea. . . . . . . . . . . . . . . . . . . . . . C-45
Distribution of Sediments in the Northern Bering Sea . . . C-60
Typical Island Profiles . . . . . . . . . . . . . . . . . C-79
Caisson Retained Island . . . . . . . . , . . . . . . . . C-87
Ice Island Plan (llnion Oil). . . . . . . . . . . . . . . . c-93
●1.0 INTRODUCTION
1.1 Purpose
In order to analyze the-socioeconomic and environmental impacts of Norton
Sound petroleum exploration, development, and production, it is necessary to
make reasonable and representative predictions on the nature of that develop-
ment. The petroleum development scenarios in this report serve that purpose;
they provide a “project description” for subsequent impact analysis. The
socioeconomic impact analysis of Norton Sound petroleum development postu-
lated in this report will be contained in subsequent reports of this study
program.
Particularly important to socioeconomic studies are the manpower, equip-
ment and material requirements, and the scheduling of petroleum develop-
ment. The scenarios have to provide a reasonable range of technological,
9
economic, and geographic options so that both minimum and maximum devel-
opment impacts can be discerned. The primary purpose of this report is, &
therefore, to describe in detail a set of petroleum development scenarios
that are economically and technically feasible, Eased upon available esti-
mates of oil and gas resources of Norton Sound.
●
It should be emphasized that this petroleum scenarios report is speci-
fically designed to provide petroleum development data for the Alaska
OCS socioeconomic studies program. The analytical approach is structured
to that end and the assumptions used to generate scenarios may be subject to 9
revision as new data become available. Within the study programs that are an
integral part of the step-by-step process leading to OC.S lease sales, the
formulation of petroleum development scenarios is a first step in the study
program coming before socioeconomic and environmental impact analyses.
This study, along with other studies conducted by or for the Bureau of
Land Management, including the environmental impact statements produced
preparatory to the 0(3 lease sales., are mandated to utilize U.S. Geological
Survey estimates of ,recoverable oil and gas resources in any analysis requi-
ring such resource data.
●
1.2
The
the
.xE
petroleum development scenarios formulated in this report are for
proposed OCS Bering-Norton Lease Sale No. 57 currently scheduled for
November 1982.
Ocs ,
The study area
This is the
considered in
first lease sale scheduled for the Bering Sea
this report is that recommended for the lease
sale area by the U.S. Geological Survey in Open-File Report 79-720 (Fisher et
al., 1979, p. 37-38). This area is bounded in the east by longitude 162° Id,
in the west by longitude 170° W,in the north by latitude 65° N, and in the
south by latitude 63° N (Figure l-l). Along the shoreline of Norton Sound,
the Seward Peninsula and northeastern St. Lawrence Island, the lease area
boundary lies seaward of the 3-mile limit of state waters. This area covers
approximately 40,000 sq. kilometers (15,444 sq. miles). The area of tracts
actually leased will, of course, be significantly smaller due to geologic and “>,..environmental limitations{L].
Water depths in this potential
(25 feet ) in inner Norton Sound to
the Bering Sea midway between St.
lease area range
a maximum of about
from about 7.5 meters
55 meters (180 feet) in
Lawrence Island and the Seward Peninsula;
most of Norton Sound east of Nome is characterized by water depths of 18
meters (60 feet) or less. Sea ice covers most of the lease area from six to
eight months of the year although multiyear floes do not occur south of the
Bering Strait.
The principal components of’this study which are an integral part of the
scenario development include:
o A review of the petroleum technology that may be required to
develop Norton Sound oil and gas reserves, including its costs,
and related environmental constraints to petroleum engineering
(oceanography, biology, geologic
k (1) The call for tract nominations for
hazards, etc.}.
the Norton Basin lease sale wasF issued in May 1979 and at the time of writing (September 1979) tract se-
lection was underway at the BLM, Alaska OCS Office.
;,,- 1 . — —--—~. . ..-
-
F “i~_u_—.. — -—
-—
-AL-f“ $3,.1.)
%’
9
*
A rev
late
ew of the petroleum geology of Norton Basin to formu-
reservoir and production assumptions necessary for the
economic analysis and, if possible, provide field size distri-
bution data and prospect identification for scenario specifi-
cation and resource allocation.
An economic analysis of Norton Basin petroleum resources in
the context of projected technology and its costs.
An analysis of the manpower requirements to explore, develop,
and produce Norton Basin petroleum resources in the context
of projected technology, and environmental and logistical con-
straints.
A facilities siting study to identify suitable sites for
major petroleum facilities including crude oil terminals and
LNG plants.
The U.S. Geological Survey resources estimates used in this study are as
follows (Fisher et al., 1979):
Minimum Mean Max i mum
Oil (billionsof barrels
Gas (trillionsof cubic feet
0.38 1.4 2.6
1.2 2.3 - 3.2
This study describes scenarios corresponding to the minimum, mean, and
maximum resource estimates and for descriptive purposes terms them“low find”, “medium find”, and “high find”, respectively. In addition,
a scenario is described which assumes exploration only with no commercial
discoveries made.
4
1.3 Data Gaps and Limitations
In the course of this study, significant data gaps were revealed that
imposed limitations on the scenario development and the related analyses
listed above. These data gaps and related constraints should be kept
in mind when considering the results of this study,
The data gaps to a large extent result from the fact that industry and
regulatory agency interest and research is only now beginning to focus
on the Bering Sea basins and Norton Sound in particular. To date, research
has been principally focused on the North Slope/Beaufort Sea area, Lower Cook
Inlet, and Gulf of Alaska.’ Norton Sound is much more a frontier area than
these areas, and predictions on petroleum technology, its costs, resource
economics, manpower and facility requirements, and facility siting are far
more
1.4
This
Thus
●
speculative. In summary, the principal data gaps include:
o Oceanography - sea ice, wave, and current data required for
platform and pipeline design are limited. ‘m
* Petroleum facility costs (platforms, pipelines, terminals, etc.) -
no petroleum exploration and production has yet taken place in
areas with closely similar oceanographic conditions to provide a
firm data base for petroleum facility costs in th
area.
* Petroleum geology - insufficient geophysical data
s sub-arctic
ias available
to identjfy structures and estimate thickness of reservoir rock
sections, necessary data to estimate potential field sizes and
their location.
Report Content and Format
report is structured according to the scenario development process.
, the focus of
related analytical
the main body of this report is the methodology and
assumptions in scenario development (Chapters 3.0 and 9●
●5 “
I4.0) and the description
(Chapter 5.0), high find
low find (Chapter 8.0).
The research findings of
strutted, are presented
of the economic analysis
of the scenarios themselves
(Chapter 6.0), medium find
this study, upon which the
-- exploration only
(Chapter 7.0), and
scenarios are con-
in the appendices commencing with the results
(Appendix A). The subsequent appendices detail
the cost estimates used in the economic analysis. (Appendix B), petroleum
technology (Appendix C), petroleum facilities siting (Appendix D), and
employment (Appendix E}. Alternative employment estimates for the Norton
Basin scenarios demonstrating the sensitivity of such estimates to certain
seasonality, scaling and production’ assumptions are given at the end of
Appendix E. The results of a marketing study concerning future oil and gas
production from the Norton Basin are presented in Appendix F.
This report commences with a summary of findings (Chapter 2.0) under the
headings of Petroleum Geology anti Resource Estimates, Selected Petroleumi Development Scenarios, Employment, Technology, and Resource Economics.
.
c
2.0 SUMMARY OF FINDINGS
2.1 Petroleum Geology and Resource Estimates
The resource estimates that form the basis of
scenarios in this report are the U.S. Geological
covered recoverable oil and gas resources. These
Minimum Mean
Oil (billionsof barrels) 0.38 1.4
Gas (trillionsof cubic feet) 1.2 2.3
the petroleum development
Survey estimates of undis-
are (Fisher et al., 1979):
Maximum
2.6
3’.2
These are “unrisked” estimates derived from probabilistic estimates
removing the marginal probabilities that were applied because Norton Basin
a frontier area. For descriptive purposes, the scenarios corresponding
●
by
is
to
minimum, mean, and maximum resource estimates are termed “low find”, “medium
find”, and “high find”, respectively.
A set of reservoir and production assumptions were formulated for the econo-
mic analysis based on available geologic/analog data and the need to explore
the economic impact of geologic diversity. Nevertheless, the reservoir and
production assumptions should bracket expectations indicated by the available
geologic data and/or extrapolation from reasonable analogs.
Because detailed geophysical data was unavailable to this study and because
there is no drilling history in this basin, formulation of reservoir and
production assumptions has had to rely on analog basins. These analogs are
producing Pacific Margin tertiary basins such as Cook Inlet in Alaska. In
addition non-producing Pacific Margin Tertiary basins such as the Anadyr
Basin of northeast Siberia provide analogous geologic data and valuable clues
(strati graphy, structural history and so forth) to extrapol ate. or better
predict the geologic characteristics of the Norton Basin. The reservoir and
production assumptions listed below generally fal’1 within the geologic,
●
o●
7
reservoir and production characteristics typical of such basins. The assump-
tions are:
* Average reservoir depths (gas and oil) - 762 meters (2,500 feet),
1,524 meters (5,000 feet), and 2,286 meters (7,500 feet).
● Recoverable reserves per acre - 20,000 bbl and 60,000 Ml.
s Well spacing - variable, consistent with ranges in known producing
fields.
s Initial well productivity, oil - 1,000, 2,000, and 5,000 bpd.
9 Initial well productivity, gas - 15 and 25 mmcfd.
@ Gas resource allocation between associated and non-associated
for scenario detailing and analytical simplification, all
the gas resources are assumed to be non-associated (i.e. scenarios
are detailed which include gas field(s) totaling the U.S.G.S. gas‘1) oil fields are implicitly assumed, there-resource estimate);
fore, to have a low gas-oil ratio (GOR) and that associated gas is
uneconomic ”and is used to fuel platforms with the remainder rein-
fected.
e A low”gas-oil ratio is assumed for analytical simplification
(see bullet above).
e No assumption was made on the physical properties of the oil;
the range of prices used in the analysis is partly a function
of the potential range in crude qualities.
(1) It is recognized, however, that in reality some portion of the gasresource will be associated.
9
In the absence of sufficient geologic data to make reasonable predictions on
a number of prospective structures and field sizes that may be discovered in
Norton basin, the field sizes selected for economic screening have, there-fore, been selected to be consistent with the following factors:
o Geology (only gross structural geology and stratigraphic data are
available).
● Requirement to examine a reasonable range of economic sensi-
tivities.
The field sizes to be evaluated in this study, therefore, range from 100
million barrels to two billion barrels for oil and 500 billion cubic feet to
three trillion cubic feet for non-associated gas.
FieJd location in the scenarios is arbitrary but designed for impact assess-
ment to provide a range of development cases that are shown to be economi-
cally and technically realistic options.
2.2 Selected Petroleum Development Scenarios
Four scenarios are detailed describing exploration only (no commercial
resources discovered), a high find case assuming significant commercial
discoveries, medium find case assuming modest commercial discoveries,
and low find case assuming marginal commercial discoveries.
2.2.1 Exploration Only Scenario
The exploration only scenario postulates a low level of exploration with only
eight wells drilled overa period of three years (Table 2-1). Exploration is
conducted principally in the four month summer openwater season using jack-up
rigs augmented by dril”lships. Two of the wells are drilled from gravel
islands constructed in summer. No new onshore facilities are constructed.Nome serves as a forward support base for light supplies and provides aerial
support for offshore activities; heavy materials are stored in freighters
●
●
●9
TA13LE 2-1
EXPLORATION ONLY SCENARIO - LOW INTEREST LEASE SALE
YEAR AFTER LEASE SALE1 2 “ 3
Rigs Wells Rigs Wells Rigs Wells
2 2 3C 4 lC 2
lG lG
TOTAL WELLS = 8
C= Conventional rigs (jack ups or drillships)G= Gravel island
Assumptions:
2. An average total well(10 ,000 to 13,000 feet).
● 3. Year after lease sale4. Rigs include jack upssummer-constructed gravel
Source: Dames & Moore
1. An average well completion rate of approximately 4 months.depth of 3,048 to 3,692 meters
= 1983.and drillships in summer and some~slands in shallow water.
10
. . . . . . . . . . . . . . . . . . . . . ., . . -- —.---’ --. --- .--. ..-..,. -.
and barges moored in Nod and transshipped to the rigs via supply
boats and there is a reacated in the Aleutian Islands.
2.2.2 High Find Sc
The high
and gas.
find scenario significant commercial discoveries of oil
The total resowred and developed are:
Oil (MMBBL) Non-Associated Gas (BCF)
2,600 3,200
These resources are dd in three “clusters” of fields located
respectively in inneround south of Cape Darby, central NortonSound south of Nome, aflorton Sound about 64 kilometers (40 miles)
southwest of Cape Rodnej
All oil and gas produbrought to shore by pipeline to a large
crude oil terminal andt located at Cape Nome. Production from
the central Norton Sas involves a direct offshore pipeline to
Cape Nome while produ~ the outer and inner Norton Sound fieldsinvolves a significant oeline segment.
Oil production from Nnd commences in year 7 (1989) after the
lease sale, peaks at 7( in year 13 (1995), and ceases in year 34
(2016) . Gas productionmences in year 7 (1989), peaks at 691,200●
mmcfd in years 13 thri995 through 1999), and ceases in year 34 -
(2016).
The basic characterisbis scenarib are summarized in Tables 2-2
and 2-3.
2.2.3 Medium Find
The medium find scenarinodest discoveries of oil and non- 9e11 ●
.— ——— —.. . . .
—
TABLE 2-2
HIGW FIND OIL SCENARIO
FieldSizeOil
!!!!xQ
[
500
200
1200
(
500
I200
[
750
\250
Location
InnerSound
InnerSound
InnerSound
CentralSound
CentralIsland
OuterSound
OuterSound
ReservtNeter:
2,286
2,286
2,286
2,286
2,286
2,286
2,286
O&h
7,500
7,500
7,500
7,500
7 , 5 0 0
7,500
7,500
Production System
Gravel island sharedpi pel ine to shoreterminal
Gravel island withshared pi pel ine toshore terminal
Gravel Islandshared pipel ine toshore terminal
Steel platforms withshared pipeline toshore terminal
Steel platform withshared pipel ine toshore terminal
Steel platforms withshared pipel ine toshore terminal
Steel platform withshared pi pel ine toshore terminal
* S = Ice reinforced steel ~latform.G = Caisson retained grav;l island.
Fields in same bracket share trunk pipel inc.
So~rce: Oames & Moore
PlatformsNo. /Type’
2 G
lG
lG
2 s
1 s
3 s
1 s
Number ofProduction
Uells
80
40
40
80
40
120
40
Initial WellProductivity- - J @ - - -
2,000
2,000
2,000
2,000
2,000
2,000
2,000
Peakproduction)il (MB/U)
153.6
76.8
76.8
153.6
76.8
230.4
76.8
mMeter:
18
18
]8
18
21
30
30
@&
60
60
60
60
70
[00
100
ipeline [o Shore 1ilometers
133
146
150
34
58
129
140
tanceminalm
83
91
93
21
36
80
87
Trunk~ipelineliameter,inches)Oil
20
20
20
16-18
16-18
20
20
Shore[erminal.ocation
CapeNome
CapeNome
CapeNome
CapeNome
CapeNome
CapeNome
CapeNome
I--4
cd IiFieldSizeGasBCF
1$00
1,000
L1,200
Location
CentralSound
CentralSound
1-CentralSound
I?eserva——Meters
2,286
2,286
L2,286
?,500
7,500
Steel PI at forins withshared pipel im! toLNG plant
Stefl platform withshared pipeline toLNG plant
E* S = Ice reinforced steel platform.
“ Fields in bracket share same trunk pipel inc.
Source: Dames & Moore
@9
FABLE 2-3
HIGH FIND NON-ASSOCIATED GAS SCENARIO
PI atforms&Q!Yll&
Is
1 s
1 s
Number ofProductionWells
16
16
16
Initial IJellProductivity
(i4kicFD)
15
1 5
15
PeakProduct ionGas (MMCFD~
240
J240
240
_Meter:
20
18
20
L@&‘eet
66
60
66
‘ioeline” Distance:o- Shore “:i 1 ometer:
51
43
51
rnirialm
32
27
32
Trunk‘ipel ine)i ameter[inches)Gas
24-28
24-28
20-24
LNGPlant
CapeNome
CapeNome
CapeNome
P ●
. . .
associated gas. The basic characteristics of the scenario are summarized in
Tables 2-4 and 2-5. The total reserves discovered and developed are:
Oil (MMBBL~ Non-Associated Gas (BCF)
1,400 2,300
Five oil fields comprise the total reserves. They are located in two
groups of fields, one in inner Norton Sound, the second in
sound south of Nome, plus a single field in the outer sound
Cape Rodney. The gas reserves are contained in two fields
to each other about 48 kilometers (30 miles) south of Nome.
the central
southwest of
ocated close
All crude is brought to a single terminal located at Cape Nome. For the
inner sound fields, this involves a 100-kilometer (62-miTe) onshore pipeline
segment from Cape Darby to Cape Nome; the trunk pipeline from the central and
outer sound fields makes landfall close to the terminal site and, therefore,
!nvolves minimal onshore pipeline construction.
The non-associated gas fields share a single trunk pipeline to a LNG plant
located adjacent to the crude oil terminal at Cape Nome.
Oil production from Norton Sound commences in year 8 (1990) after the
lease sale, peaks at 463,000 b/d in year 12 (1994), ,and ceases in year 29
(2011). Gas production commences in year 7 (1989), peaks at 460.8 mmcfd
in years 12 through 18 (1994 through 2000), and ceases in year 28 (2010).
2.2.4 Low Find Scenario
The low find scenario assumes small commercial discoveries of oil and
non-associated gas. The basic characteristics of the scenario are summarized
in Tables 2-6 and 2-7. The total reserves discovered and developed are:
Oil (MMBEIL~ Non-Associated Gas (BCF)
380 1,200
14
FieldSizeOil
l!!!!xl
[200
I200
[
500
250
1250
Location
InnerSound
InnerSound
CentralSound
CentralSound
OuterSound
Reservileter
2,286
2,286
2,286
2,266
2,286
r DeptlFeet
7,500
7,500
7,500
7,500
7,500
Production System
Gravel island withshared pipeline toshore terminal
Gravel island withshared pipeline toshohe terminal
Steel platforms withshared pipeline toshore terminal
Steel platform with”shared pipeline toshore terminal
Steel platform withshared pipeline to.shore terminal
* S = Ice reinforced steel platform.G = Caisson retained gravel island.
Fields in same bracket share trunk pipeline.
Source: Oames & Moore
●
TA8LE 2-4
klEDIUM FIND OIL SCENARIO
1PlatformsNo. /Type*
IG
IG
2s
Is
Is
Number ofProduction
Wel 1s
40
4G
80
40
40
fnitial well%-oductivitj
(9/D)
2,000
2,000
2,000
2,000
2,000
PeakProduct ionJil (hill/D)
76.8
76.8
153.6
76.8
76.8
&e
Ml
18
18
21
30
~
60
60
60
70
100
Pipeline Ito ShoreKilometer:
133
146
34
58
9 5
stanceminalMiles
83
91
21
34
59
TrunkPipe] inJiamete[inc~s
14
14
18
18
18
ShoreTermina’Locatiol
CapeNom
CapeNome
CapeNome
CapeNome
CapeNome
ao
● a ● ●
-
Ef-FieldSizeGasBCF Location
1,300 CentralSound
1,000 CentralSound
Reservoir Oe th
7
Meters Feet
2,286 7,500
2,286 7,500
Production System
Steel platform withshared pipeline toLNG plant
Steel platform withshaked pipeline toLNG plant
● s= Ice reinforced steel platform.
TABLE 2-5
MEOIUM FIND NON-ASSOCIATED GAS SCENAR1O
-1__1 s 16
Initial MenProductivity(MWFO)
15
15
PeakProduct ion~
240
240
TrunkPipel ine
Pipel ine Distance DiameterWater Oepth to Shore Terminal (inches)Meters Feet Kilometers Miles Gas
20 66 48 30 20
18 60 32 20 20
LNGPlant
CapeNome
CapeNome
Fields in bracket share same trunk pipel inc.
Source: Oames & Moore
TABLE 2-6
LOW FIND OIL SCENAR1O
e
FieldSizeOil_
(
200
[
180
Location
CentralSound
CentralSound
I I II I I Number of
Reservoir Depth. PI at forms PnxlfigionMeters] Feet Production System No. /Type*
2,286 7,500 Steel platform with I I1 s 40shared pipeline toshore terminal
I I2,286 7,500 Steel platform with I I1 s 40shared pipeline toshore terminal
* S = Ice reinforced steel platform.
Fields in same bracket share trunk pipeline.
Source: Dames & Moore
Initial blellProd;;; ivi ty
2,000
2,000
PeakProductionOil (M8/0)
76.8
76.8
Water De th
T
Meters Feet
21 70
21 70
●
~ipeline Distance:0 Shore Terminal;ilometersl Mi]es
34 21
58 36
e
TrunkPipe] ioeDiameter[i~;es)
14
14
ShoreTerminalLocation
CapeNome
CapeNome
FieldSizeGas
l!%!.
1,200
Location
CentralSound
I?eservt-fZ.%’R
2,286
+%&7,500
* S = Ice reinforced steel platform.
Production System
Single steel plat-form wit h unsharedpipeline to LNGpl ant
TABLE 2-7
LOW FIND NON-ASSOCIATEO GAS SCENARIO
PI atfonnsNo. /Type*
1s
Number ofProduct ion
Wel Is
16
Initial Well PeakProduct ionGas (klMCFD}
240
L NGPlan!
CapeNome
m
Source: Dames & Moore
These reserves, especially the gas, are barely economic to develop. The oil
reserves comprise two fields located between 34 and 58 kilometers (21 and 36
miles) southwest of Nome while the non-associated gas reserves occur in a
single field located about 34 kilometers (21 miles) south of Nome. No
discoveries are made in the inner or outer sounds.
Two trunk pipelines, both about 34 kilometers (21 miles) long, transport the
oil and gas production direct to a crude oil terminal and LNG plant, respect-
ively, located at Cape Nome. Minimal onshore pipeline construction is sinvolved in the development of these fields.
Oil and gas production from Norton Sound both start in year 8 (1990).
Oil production peaks at 153,000 b/d in year 11 (1993) and ceases in year 27
(2009) . Gas production peaks at 230.4 mmcfd in years 11 through 19 (1993
through 2001 ), and ceases in year 32 (2014).
2.3 Employment
Estimates of manpower requirements are presented in a ser. es of four tables
for each scenario. These are found in Sections 5.0 through 8.0. Definition
of terms used to describe manpower requirements are found in Appendix E.
●
Maximum employment is created in year 9 of the High Find Scenario, when
63,307 man-months of work will be generated (equivalent to an average of
5,276 people per month during the year; peak employment during the year would
be higher). Maximum employment is created in year 8 of the Medium Find and*
Low Find Scenarios,
42,649 man-months,
respectively.
and year 2 of the Exploration Only Scenario, generating
16,506 manmonths, and 3,445 man-months of employment,
Manpower requirements for onshore activities peak earlier than for offshore
activities in the three scenarios that involve fiel~ development. Onshore
(on site) labor requirements peak in year 5 in the High Find Scenario at16,498 man-months, and offshore (on site) labor requirements peak ifl year 9 ●o
..—.-———. .-
at 27,328 man-months. In the Medium Find Scenario, onshore [on site) labor
requirements peak in year 5 with 9,138 man-months, and offshore (on site) in
year 9 with 17,802 man-months. In the Low Find Scenario, onshore (on site)
peaks in year 7 with 4,173 man-months, offshore (on site) a year later with
6,978 manmonths. This pattern occurs because construction of the major
onshore facilities is begun before most of the platforms are installed,
pipeline laid, and production wells drilled, activities that cluster in years
6 through 9.
During the middle of the production phase, onshore labor will average 525
people per month (on site; 810 people total), and offshore labor will
average 1,605 people per month (on site; 3,120 people total) in the High
Find Scenario. In the Medium Find Scenario and LOW Find Scenario, onshore
labor will average 327 and 135 people per month respectively (on site; 523
and 222 people total), and offshore labor will average 1,056 and 321 people
per month respectively (on site; 1,964 and 624 people total).
Manpower requirements for each scenario are summarized in Tables 2-8 through
2.4 Technology and Production Systems
In an oceanographic comparison with Upper Cook Inlet, on the one hand,
and the Beaufort Sea, on the other, Norton Sound and adjacent areas of
the Bering Sea have certain attributes of both and yet are unique in other
aspects. Norton Sound is shallower than Upper Cook Inlet, deeper in general,.than the Beaufort Sea lease area, and has ice conditions in terms of duration
intermediate to both. Water depths range from 7.5 meters (25 feet) off the
Yukon Delta (i.e. at the three mile limit) to over 46 meters (150 feet) in
the outer sound between St. Lawrence Island and the Seward Peninsula. Pack
ice up to 12 meters (4O feet) thick has been reported in the Bering Sea
although floe ice within Norton Sound is generally up to 2 meters -(6.5 feet)
thick. Shorefast ice extends shareward of the 10-meter (33-foot) isobath. A
maximum wave of about 4.3 meters (I4 feet) can be anticipated in Norton
Sound.
20
(filhN-ml)iTlis)AWEHAGE
(iiW+E~” OF PEOPLE1
9e
u-iIJ-s
.
,.1r;P
.1
. .,, . . . . . . . . . . . . . . ...3 . . . . . . . . .., ;-., .::r,: :,-t - . . .. fc k.=.. 3;<-...’. ,-, ,
1 ., - F--- A1LLLLA T. \\\,.1,.,\-,.--:. ,4:
(if\--. .rr*:!r (. . . . . . -.\lr?? l--- *.\!lf’,r,ff~, r.(. .r, .r, rr r.- ,! .,:.-,.-,\, .u-, -- -,,. L. LLl.. kL\. \v \\.,<~.---
.
-.
J,
..-, :5
r .U..J-eu. <J
22
ml-d
MEDIUM FIND SCENAR1O0%/!24/79
YEAR AFTERLEASE SALE
3456789
lo11121314151617
21222324252627282930
ONSITE{MAt+MOt4THS~
U!-tbHuuk2243,5.W2.6448.5036.4090.13194e11228.17290.17802.16.?24.13320.12108.12132.12492.12672.12672.!.2672.12672.i2672.12672.12672.11388.10104.10104,10IO4*1010407356.6072.36’84.2400.
UNSHURk
334.7EJ6.924.
4044 ●
9138.453A .3209.7962.4s20.4116.4062.396o.3924.3924.3924.3924.3924.3924.3924.3924.3924.3672.342o.3420.34.20.342o.2916.t944.432.180.
TAME 2-10
SUMMA*Y OF MANPoidER RE63uIREHENTs F O R ALL lNOusTRIES
TOTAL
2577.6B2M.737.2.9080.13229.17726.14437.25252.22322.20340.i7382.16068.16056.164]6.165’26.16596.16596.16596.16596.16596.16!596,15060.13524.13524.13524.13524.10272.8016.4116.2S60 ,
99 TOTAL XNCLLJOES ONSITE AND OFFSXTE
— .—-ONSITE AN6 TO~AL-O*
TOTAL TOTAL MONTHLY AVERAGE(MAN-MONTHS) (NUMBER OF PEOPLE)
OFFSHORE ONSHORE TOTAL OFFSHORE ONSHORE
3899.9406.!1264.8748.7095,
23843.2063t3.32161,33782.30672.24864.22440.22w38e2320be23S66.235613.23560,23566.23566.23568.23566.21072.18576.18576.18576.18576.13224.10728.6096.3600.
454.1069.1251.4658.10210.5132.5!58.10489.6751.6344*6290.6188.6152.6152.6152.6152.bls2.6152.6152.6152.6152.5840.5528.5528.552M.5528.4904.3152.512.200.
4353.10475*12515.13406.17306.28975.25796.426~9e40532.3 7 0 1 6 .31154028628.28640.29360.29720.29720.29720.29720.29720.29720.29720.26912.24104.24104.24104.24104.18128.13880.6608.3800.
325.7B4.939*729.592.1987.1720.2680.2816.2556.2072.1870.1874.9934.1966.1964.1964.1964.1964.1964.1964.1756.1548.1548.1548.1540.1102.b9&.SOB.300.
38.90.
105.389.851.428.430.874.563,529.525.516.513.513,513.513.513,513..513*513.5i3.407.461.461.461.-
461.ko~.263.43.17.
●
TOTAL
363.873.1043.1118.1443.24A5.2150.3555*3378.3085.2597.2386.2387.2447.2477.2477.2477.2477.2477.2477.2477.2243.2009.2009.2009.2009.151k.1157.551.3170
— —
Ivb
LOW FIND SCEtdAKl130 9 / 2 4 / 7 9
VEAI+ AFTERLEASE SALE
14151617181920212223242s2627282 930
urr >numc
~4]2.2518.3624.5 0 3 6 .2 2 1 2 .4 2 6 2 .6098.6978.6 3 8 4 .4 6 5 6 .3480,3312.3852.3852.385.?.3852.385.2.3852.3b5Z.3852.3852.3852.2748.2748.2658.256d.2~68.1284.1284.1284.
ONSITE(MAN-MONTHS]
‘r’_”’’’”’- ON5H06E
216.3 5 4 .4 9 2 .7 0 8 .
1154.2454.&A73.1820.1692.176~.1638.1620,1620.1620.1620.1620.1620.1620.1620.1620.1620.1620.1368.1368.1368.1368.984.732.732.732.
TABLE 2-11
SUMMARY OF MANPOWER REQUIREMENTS FOR ALL KNousTRIEs
TOTAL
162B.2872.4116,5744.3366.6716.10272.8797.8076.6420.511804932.51+72.5472.5472.5472.5472.5472.5472.5472.5472.5472.4116.4116.4026.3936.3552.2016.2016.2016.
ONSITE AND TOTAL *O
TOTAL(MAN-MONTHS)
OFFWORE ONSHORE
2516.f4374.6232 ;8748.3716.7817.11555*13622.12552.9096.6744.6408.7488.7488.7488.7488.7488.7488.7488.7488.7488.7488.5352.5352.5172.“4992.4992.249b-2496.2496.
296.477.659.955.
1337.2774.4:34.2884.2736.2808.2682.2664.2664.2664.2664 ●
2664*2664.2664.2664.2664.266h.2664.2352.2352.2352.2352.1584.1272.127201272.
TOTAL
2612*4851.6891.9703.5053.10591.16189.16506.15288.11904.9426.9072.
1015.2.10152.10152.10152.1015Z.10152.10152.10152.10152.10152.7704.7704.7524,7344.6576.3768.3768.3768.
TOTAL MONTHLY AVERAGE[NUM8ER OF PEOPLE)
OFFSHORE ONSHORE
210.365.520.729.310.652.963.1136.1046,758.562.534.624.624.624.424.624.624.624.624.624,624,446.446.431.416.416.20&,208.208.
25.40.55.80,1126232.387.241.228.234.224.222*222*222.222*222.222.222.222.222.222.222*196,1’36.196.196.132.106.106.106.
TOTAL
235./+05.575.809.422.883.1350.1376.1274.992.786.756.846.846.846.846.846.046.846.846.846.846.642.642.627.612.548.314.3140314.
** TOTAL INCLUDES ONSITE AND OFFSITE
.
These preliminary oceanographic findings in conjunction with design criteria
for Upper Cook Inlet steel platforms indicate that modified Upper Cook Inlet
type platforms may be feasible for operation in Norton Sound. This conclu-
sion is tentative since sufficient oceanographic data to adequately assess
platform design requirements does not yet exist. However, such platforms, as
opposed to the monotone proposed for Eleaufort Sea operations, may be the more
likely development strategy. In shal lower waters (less than 18 meters [60
feet]], gravel islands may also be a development alternative especially the
caisson-retained design. The economic analysis, therefore, has evaluated the
economics of these platform types for the following water depths.
Platform TypeWater Depth
meters feet
Ice reinforced steel platform 15 50(modified Upper Cook Inlet Design) 100
:: 150
Gravel Island 7.6 2515 50
Pipeline distances representative of potential discovery situations (in the
context of geography) were identified for economic screening as shown on
Table 2-12. In addition to development cases assum’ing pipelines to an
onshore crude oil terminal or LNG plant, offshore loading from a production/
storage/loading island was considered in the economic analysis for compara-
tive purposes although the costs of such a system are rather speculative.
Given the estimated oil and gas resources of the Norton Basin, al? the
development options considered in the analysis assumed tankering of crude or
LNG to lower 48 markets.
●
‘a
●
●
Construction schedules and manpower estimates assumed extensive modu?ariza-
tion and integration of onshore and offshore facilities to minimize local
construction and speed construction schedules because of the short summer
weather window of four to six months.
●o
TABLE 2-12
REPRESENTATIVE PIPELINE DISTANCES TO NEARESTTERMINAL SITE EVALUATED IN ECONOMIC ANALYSIS
Pip~lin~ LengthWater Depth of Field Offshore Onshore
Case meters (feet) kilometers (miles) kilometers (miles)
No. 1 15 (50), 30 [100), 46 (150) 128 (80) 3 (2)
No. 2 15 (50), 30 (100), 46 (150) ““ 64 (40) 3 (2)
No. 3 15 (50) 32 (20] 48 (30)
No. 4 15 (50) 32 (20) 3 (2)
No. 5 15 (50) 16 (10) 3 (2)
Note: Both shared and unshared p
Source: Dames & Moore
peline cases are screened in the economic analysis.
. .
2.5 Resource Economics
The economic ctiaracteristics of several likely oil and gas production
systems suitable for the harsh and icy conditions of the Norton Sound
are analyzed in this report with the model described in Chapter 3.00
The model is a standard discount cash flow algorithm designed to handle
uncertainty among the variables and driven by the investment and revenue
streams associated with a selected production technology.
9
The analysis focuses attention on: (1) the engineering technology re- .@
quired to produce reserves in the Norton Sound, and (2) the uncertainty
of the interrelated values of the economic and engineering parameters.
In view of the uncertainty, it is important to emphasize that there is
no single-valued solution for any calculation reported in the analysis.
Field development costs associated with the different production systems
as well as oil and gas prices have been estimated as a range of values.
Sensitivity and Monte Carlo procedures have been used to bracket rather
than pin-point the decision criteria calculated with the model.
Two vital
e
@
130th are
pieces of information are estimated in the analysis:
The minimum economic field size to justify development of a
known field with a selected technology in Norton Sound.
The minimum required price to just
in Norton Sound.
fy development of a field
*
very sensitive to the location of the discovered field in Norton
Sound and the decision to offshore load or pipeline. to a shore terminal as
well as the value of money used to discount cash flows. The calculated●
minimum field sizes for different production technologies are bracketed
between 10 percent and 15 percent discount rates. Tables A-2 through A-=8
(Appendix A) show the results. The calculated minimum required price for
representative oil production systems assuming a 15 percent discount rate is●
shown on Figure A-3 (Appendix A). Figure A-4 (Appendix A) shows the repre-0
sentative minimum required gas price.
●
27
The essential findings of this report are summarized below. The single
value calculations discussed are based on the mid-range parameter values.
Monte Carlo distributions and sensitivity analyses showing the range of
values for the after tax return on investment are discussed in Section
11.4 of Appendix A. The technology, financial, reservoir, and production
assumptions of the analysis are detailed in Chapter 3.0.
e The magnitude of the investment costs together with high oper-
ating costs in the Norton Sound imply that very good reservoir
conditions -- regardless of size of field -- will
to earn in excess of 15 percent return on investment.
e Platform production facilities are so costly in the
be required
Norton Sound
that shallow reservoirs which allow only eight producing oil
wells or four gas wells (assuming standard industry well-spacing)
are not economic to develop given the other assumptions of the
analysis.
@ Intermediate depth reservoir targets that restrict oil platforms
to 24 producing wells (assuming standard industry well-spacing)
are only marginally economic to develop --’given the other
assumptions of the analysis.
e Either faster recovery than 2,000 b/d per well initial production
rate or wellhead prices higher than $18.00 are required to
development of shallow to intermediate reservoir targets
Norton Sound.
justify
in the
o The minimum field size to justify development of a deep reservoir
field depends on the production technology -- offshore loaded
or pipeline to shore -- and the length of the pipeline. For a
field with an, unshared 32 kilometers (20 miles) pipeline, and a
40 producing well platform, mid-range development costs wouldbe $803.5 million and minimum field size would be 16(I million
barrels to earn 10 percent; 240 million barrels to earn 15
percent.
. . . .
0
In the relatively shallow waters of the Norton Sound, minimum field 0●
size to earn 15 percent varies between 200 and 240 million barrels ●
as water depth increases from 15 to 45 meters (50 to 150 feet).
Platform development costs rise from $704.5 million to $803.5
0
*
million as water depth
feet) -- assuming a 40
pipeline.
increases from 15
well platform and
to 45 meters (50 to 150
32 kilometers (20 miles)
In the Norton Sound where geologic conditions suggest 1,000
b/d initial production rates might be expected, platforms will ●
need to house more than 40 producing wells to earn 15 percent,
or oil will have to be priced in excess of $20.00 a barrel.
A deep resefvoir with 2,000 b/d initial production rate requires a 9
40 producing well platform with a mid-range investment cost of
$759.1 and requires 215 million barrels to earn 15 percent.
A deep reservoir with 5,000 b/d initial production rate requires
only 20 producing wells to drain efficiently and has a mid-range
cost of $595.5 million. Minimum field size to earn 15 percent is
190 million barrels. With 5,000 b/d initial production rate a 250
million barrel field is able to earn 20 percent return on invest- *ment.
Unless fields are discovered in the Norton Sound which allow
sharing pipelines to shore, investment cost of an unshared pipeline
longer than 48 km (30 miles) is so large that no production system
is able to earn 15 percent hurdle rate of return.
●
.“ —.–“
Production start-up in the Norton Sound could be
any number of environmental hazards ranging from
inabillty to secure permits in a timely manner.
occurs relative to money invested is critical to
the economics of the t)ro.iect. A one vear “worse
delayed by
bad weatherto
When the delay
the impact on
case” delay
*
●
29
●
o
e
o
0
0
can reduce a 15.5 percent project to 13.5 percent. If 15 percent
is the hurdle rate, this changes a “go-ahead” to “no development”.
A two-year “moderate impact” delay reduces the payout to 10 per-
cent.
There are economics of scale of developing a “giant” reservoir
with two or more platforms. The minimum field size that will
support two platforms and earn a 15 percent hurdle rate of return
is 425 million barrels -- assuming 2,000 b/d wells and a 16 kilo-
meters (10 miles) pipeline.
If the bottom conditions, water depth, and gravel availability
allow, gravel islands are less costly and more economic than
steel platforms as a development option. The gravel island in
18-meters (50-feet) water earns 18 percent with maximum recoverable
reserves compared to the steel platform -- both with 32 kilometers
(20 miles) pipeline to shore.
For the isolated field too far from shore for a pipeline, off-
shore loading with storage to allow full production is extremely
economic. The minimum field size to earn 15 percent is less
than 200 million barrels.
The economic screening of gas production facilities assumed
that gas was sold at the end of the pipeline-to-shore to an LNG
processor. The analysis did not include LNG investment costs.
These costs and the cost to transport-to-market must be added
to assess the marketability of natural gas discovered in the
Norton Sound.
Gas production is sensitive to reservoir target depth and loca-
tion of the field relative to pipeline costs.
Shallow gas reservoirs that restrict the number of wells that
can be drilled from a platform are not economic unless the wells
are highly productive or prices approximate $3.25 mcf.
30
●
5
e
o
e
,.
Gas reservoirs 16 to 32 kilometers (10 to 20 miles) from shore
require gas to be priced at $2.00 to $2.25 mcf to earn
percent hurdle rate of return. A large gas field with
16 well platform could support nearly a 100 kilometers
pipeline unshared and still earn the 15 percent hurdle
a15
a single
(60 miles)
rate.●
The standard gas platform with 16 wells initially producing
15 mmcfd/wel? would require a wellhead price of about $2.35 mcf
for a 750 bcf field and $2.00 mcf for 1,350 bcf field to earn
15 percent. ●
With initial productivity of 25 mmcfd minimum required price
for the 1,350 bcf field is $1.35 mcf instead of $2.00 mcf.
The minimum required price to develop an oil field that will
earn 15 percent in the Norton Sound ranges between $26.00 and
$36.00 barrel for 100 million barrel field depending on the
development technology; between $15.00 and $18.00 brarel for a 250
million barrel field.
The Monte Carlo analysis reveals that there is a wide range to
the potential payout of either oil or gas’development as a re-
sult of the range of uncertainty built into the estimates of
cost and estimates of resource prices.
*
●
●
☛
*
31—.. .-— .
I
3.0 METHODOLOGY AND ANALYTICAL ASSUMPTIONS
3.1 Introduction
This chapter describes and explains the geologic, technical, and economic
assumptions of the economic analysis, which forms the central part of
this study, and links the various analytic tasks in the scenario develop-.,ment. The study methodology is illustrated in Figure 3-1 and the analytical
steps in the economic analysis are further explicated in Figure 3-2.
This chapter is organized to reflect the basic data flow of this study as ●
shown in Figure 3-1.
3.2 Petroleum Geology, Reservoir, and Production Assumptions
3.2.1 Introduction
The economic analysis and detailing of scenarios for offshore petroleum
development require that some basic assumptions be made about the char-
acteristics and performance of prospective reservoirs. Because the economic
analysis considers the total prospective acreage of the lease sale area and
not a single site specific prospect, the assumptior~s that are made have to be
generally representative of anticipated conditions. There are very little
published data available to guide assumptions for these parameters. Where
possible, therefore, a range of values are selel:ted for some parameters.
It should be emphasized that reservoir and production assumptions should
not be construed as an attempt to construct a reservoir model for site
specific prospects. Rather, they are formulated to evaluate the overall
*
●
resource economics of a large portion of a sedimentary basin comprising
numerous petroleum prospects which may exhibit considerable variation in
reservoir characteristics and production potential. The reservoir and
production assumptions are designed to evaluate the economic sensitivities
of geologic diversity. Nevertheless, the reservoir and production assump-
tions should bracket expectations’ indicatecl by the available geologic data ●
and/or extrapolation from reasonable analogs. o
●
33
. -
ANALYTICAL ASSUMPTIONS rEXPLORATIONONLY SCENARK(Non Economic
Resources)
BASELINE DATA REVIEWr \
+4 DescribeAccording To:
11. Schedule2. No. wells3. FacillksRequked
4. ManpowerRequiremerils
—— ---- .
hl Hydrocarbonand ProductionI
f ,11 DistributionII
I I l l — — — — — l ILOW FINDSCENARIODescribe
According To:1. Schedule2i:.T::sel
3. ConstructionSchedules
4. Facilities5. Production
by Year6. Man~owerRequirements
1. ProductionFacility Costs(Platforms,Pipetines,
rerminals etc.)2. Operation
costs +3ECONOMICANALYSIS(See Also
Figure 3-2)
DEFINEECONOMICDE;~~;P-
OPTIONS
ENGINEERINGI I
-i
PETROLEUMTECfjNNODLOG’
ENGINEERINGDefine:1. ExplorationTechnologyOpt ions2. ProductionTechnologyOptions(PlatformTypes, etc.)
3.Transportation
Options
T
MANPOWERANALYSISFor EachScenarioEstimate
Manpower:1. January,July and
Peak by Yeai2. Yearly by
Activity3. Onsitel
Off site
(SKELETALSCENARIOS
SCHEDULINGDefine:1. Exploration(~jcg~s~ells, -
Rate etc.)2. ProductionFacilityConstructionSchedules
3. FieldInvestmentFlows
ENVIRON-MENTALCONSID-
ERATIONS1.EnvironmentsConstraintson PetroleumDevelopmentandEngineering>EnvironmentsDelay
AccordingTo: re-c o m p l e t e
CON-STRUCTIONSCHEDULE
TABLES
1. ReservoirCharac-teristics
2. Field Size3. PetroleumTechnologyExploration,ProductionandransportatiorOptions& Location
9
b
—
-1
MEDIUM FINDSCENARIODescribe
According TO:1. Scfledule I2. Tracts/Acreage
1. ConstructionSchedules
$. Facilitiesj. Production
by Year
I iG-PARAMETER$Ecc
Define:1. Oil and
Gas Prices2. Royalty3. Taxes4. Operatingcosts
5. TangibleInvestments
6. IntangibleInvestments
).~
/. < . +
vEMPLOYMENTDefine
-9
I_==t &!!!!&arl-U. S,G.S.OIL AND GAS
RESOURCEESTIMATES
HIGH FINDSCENARIODescribe
According To:1. Schedule2A:;:;S,I
3. ConslructiorSchedules
4. Facilities5, Production
by Year6. ManpowerRequirements
11. Units 1
, ]2. Schedules I
I Employment d Efficiency IL
j 3. Scale and [
1 I I Factors1
Figure 3-1 LOGIC AND DATA FLOW OF DAMES & MOOREPEWK)LELJM DEVELOPMENT SCENARIO MODEL
.
.,-.
\
fTake Next ili scuvery I
I Define Distance to ShoreWater Oepth I
Figure 3-2
LOGIC AND DATA FLOWi 11
Assume Reservoir and Productioncharacter-i sti cs
Depth, Wel 1 Productivity, Oecl ineCurve, etc.
.
+ i
FORFIELD IIEVEIXWMEN’T
AND FORDISCOUNT’ CASH
IJetermi ne Size of Field: Recoverable Reserves,Requi red Number of Wel 1s to Exhaust Reserves, FLOW ANALYSIS
and Annual Production from the FieId
tDetermine Appropriate Production
Technology Production Technology
+ ?
Dril 1 Development Wel 1s at an Assumed Calculate DevelopmentYearly Completion Rate / Dri 11 ing Costs a
i i \ 1Determine Operating * Cal cul ate Operating
Technology costs1
iIv ——
Determine Transportation Alternatives to, Calculate Transportation and Storageand Storage Alternatives at, -
Point of Tanker’ LoadingInvestment and Operating Costsfor This Field’s Production
+r 1
I Produce Field IJnti 1Reserves are Exhausted I
I I
t t
}
Find Minimum Required Price,
Calculate NPV of For This Field
Revenues Minus Cost(Price that Equates
NPV Revenues and Costs)1 i L r
— t’
Sand This Production Technology
Ptiinti1. Annual Production and Cash Flows
t2. NPV of Cash Flows
The economic data. flow as ‘ 3.N o t e : Internal Rate of Return4.illustrated in this figure Minimum Price
assumes exclusion of explo- . 5. Minimum Field Sizeration costs in the analysis.
-.
9
●o
.—
There is very little geologic data on the Norton basin to make reasonable
petroleum geology reservoir assumptions. The available geologic data on the
Norton basin has been summarized in a recent U.S. Geological Survey Open-File
Report (Fisher, et al., 1979). Marine seismic data which was shot in Norton
Sound was not available for this study because processing of that data was
not completed prior to completion of this study.
Critical geologic parameters required by this anal~sis to conduct a geologic
risk evaluation and rating of prospective structures that can be adequately
defined by good quality seismic data include:
@ Probability of trapping mechanism present.
@ Indication of structural growth.
c Probability of presence of adequate thickness of reservoir rock
section.
In addition, there are two geologic parameters that only can be accurately
ascertained by outcrop and subsurface well information. These are:
● Probability of porosity and permeability present.
@ Probability of source rock present.
Outcrop data for the Norton basin is scanty at .che present time and no
wells have been drilled in the basin. Data with which to determine all
five parameters are not now available for the Norton basin. Consequently,
reliance has to be placed on use of analog basins to make reaJistic assump-
tions on some parameters.
Because detailed geophysical data
there is no drilling history in
production assumptions has had to
producing Pacific Margin Tertiary
was unavailable to this study and because
this basin, formulation of reservoir and
rely on analog basins. These analogs are
basins such as Cook Inlet in Alaska. In
) addition non-producing Pacific Marg n Tertiary basins such as the Anaciyr
Basin of northeast Siberia provide analogous geologic data and valuable clues
(stratigraphy, structural history and so forth) to extrapolate or better
predict the geologic characteristics of the Norton Basin.
The economic analysis and scenario formulation require assumptions
Initial production rate.
Reservoir depth.
Recoverable reserves.
Well spacing.
Production profile.
Allocation of the
between associated
U.S. Geological Survey gas resource estimate
and non-associated.
Gas-oil ratio (GOR).
Oil properties.
This section begins with a summary of Norton basin petroleum geology.
The description of the petroleum reservoir and production assumptions
follows.
3.2.2 Summary of Norton Basin Petroleum Geology
3.2.2.1 Regional Framework
The Norton basin lies south of Nome and the Seward Peninsula in western
Alaska. The major part of the basin is offshore on the shallow water
shelf of the Bering Sea.
9
*
e
●
3 7
The basin was formed during the late Cretaceus by crustal extension and
subsidence adjacent to a large terrace in northern Alaska that was displaced
relatively northeastward by right
Laramide orogeny.
Marginal outcrops suggest that
ceous; but the major thickness
slip on the major Kaltag fault during the
basin fill may be as old as late Creta-
is represented by sediments of Paleogene
and Neogene ages. Based on marine seismic data (Fisher, et al., 1979),
volcanic flows and sills of.Paleogene age are indicated ta be present.
These volcanic rocks may correlate with Paleogene volcanic rocks on St.
Lawrence Island which bounds the basin to the south. An Oligo-Miocene
unconformity generally separates non-marine deltaic strata below from
marine strata above.
Pre-tertiary rocks on Seward and Chukotsk Peninsulas and St. Lawrence
Island consist chiefly of Precambrian, Paleozoic and early Mesozoic non-vol-
canic sedimentary rocks. The rocks on St. Lawrence Island are nearly iden-
tical in Iithology and age to the stratigraphic sequence in the northern part
of the Brooks Range. A belt of volcanic and sedimentary rocks derived from
volcanic
Lawrence
Chukotsk
are main’
terrain underlies the Yukon-Koyukuk Cretaceus province, western St.
Island and St. Matthew Island in the Bering Sea, and the southern
and Anadyr River region in northeast Siberia. Rocks in this belt
y of late Mesozoic Age, but locally include some earliest Cenozoic
strata. Marine magnetic data (Verba et al .,1976), obtained on the Bering Sea
shelf suggest that these volcanic rocks are part of a broad magmatic arc that
swings across the shelf from western Alaska to the Gulf of Anadyr.
Based on outcrops in regions surrounding Norton basin, it seems likely
that the “basement” floor of Norton basin consists of either or both Paleo-
zoic and Mesozoic sedimentary rocks and Mesozoic volcanic rocks.
The Anadyr basin of northeast Siberia is analogous to the Norton basin
in structural style, age, and type of sediment fill and provides important
clues as to type of sediment fill in the Norton Basin. In Anadyr, Tertiary
and Cretaceus’ deposits are superimposed on Cretaceus forearc. d
the Koryak-Anadyr reg>posits of
on. Upper Cretaceus and Paleogene deposts have a
38
●
total thickness of 1,494 to 1,980 meters (4,900 to 6,500 feet). The upper
Cretaceus strata are composed of argillite and fine grained sandstone flysch
deposits. These rocks are intruded and overlain by Paleocene to lower Eocene
mafic and intermediate volcanic rocks. Upper Eocene to Oligocene terrigenous
deposits of sandstone and argillite overlie the volcanics.
Neogene sediments in the Anadyr basin have a total thickness of nearly
3,048 meters (10,000 feet) and comprise the principal fill of the basin.
More than 1,980 meters (6,500 feet) of this section is made up of middle
and upper Miocene strata which is composed of shallow marine littoral,
and coal bearing non-marine sediments. Miocene strata are overlain by
396 to 488 meters (1 ,300 to 1,600 feet) of P1 iocene strata and 61 to 122
meters (200 to 400 feet) of Quarternary deposits.
An interpretation of marine seismic data in Norton basin indicates the
sedimentary sequence here to be strikingly similar to that in Anadyr.
*
●
Poorly exposed lower tertiary volcanic and non-volcanic coal bearing deposits a
outcrop on St. Lawrence Island. An older Paleocene unit is composed primar-
ily of volcanic flows and tuffs with thin bands of Tignitic coal and tuff-
aceous sedimentary rocks. A younger Oligocene unit consists of poorly
consolidated calcareous sandstone, grit, and conglomerate, carbonaceous
,mudstone, ashy tuff, and volcanic breccia.
Two small outcrops of poorly consolidated coal-bearing beds of tertiary
age are exposed near Unalakleet along the Norton Sound coast. A small
isolated patch of conglomerate of Cretaceus or Tertiary age occurs in
the Sinuk River valley on the Seward Peninsula, 34 kilometers (21 miles)
northwest of Nome. H e r e s a n d s t o n e , shale, a n d c o a l are also p r e s e n t i n
minor amounts.
3.2.2.2 Structure
Seismic reflection data in Norton basin indicate the basin is deepest
north and west of Yukon delta. The deepest point measured is 7,010 meters
39●
(23,000 feet). West-northwest trending normal faults form grabens, which
contain the thickest basin fill. These grabens are separated by horsts over
which sediment thickness is generally shallower than 3,048 meters (10,000
feet) and more commonly less than about 1,980 meters (6,500 feet). The deep
parts of the basin are formed by progressively deeper step down fault blocks
which form a series of horsts, grabens, and half grabens. Deep in the basin,
the faults show major displacement (measured in hundreds of meters), but
above a horizon, which is generally 1,980 meters to 2,896 meters (6,500 to
9,500 feet) deep,
m e t e r s ( 3 0 0 f e e t ) .
The area of horst
the faults show minor displacement that is less than 91
This horizon may be a basin wide unconformity.
and graben structure is bounded on the north by an area
under which the bottom of the basin forms a platform that slopes gently
basinward. The platform is shallow, less than 1,067 meters (3,500 feet)
deep, and forms a relatively smooth surface. A normal fault forms the
southern limit of the platform in most
o c c u r s b e t w e e n $t. L a w r e n c e I s l a n d a n d
The ages of strata in the basin are
places. A fault-bounded platform also
the Yukon delta.
not well known. Based on refraction
seismic data by Fisher, 1979, and comparison of these data with similar
data in the Anadyr basin, the pronounced unconformity within the basin
fill probably occurred between the Oligocene and Miocene. T h e depositional
e n v i r o n m e n t o f t h e strata n e a r t h e u n c o n f o r m i t y i s i n t e r p r e t e d f r o m t h e
a c o u s t i c s i g n a t u r e o f t h e s e i s m i c d a t a . Reflections j u s t below t h e u n c o n -
formity are mostly irregular and discontinuous, possibly indicating localized
sediment units in fluvial or deltaic systems. The sequence of irregular
reflections is widespread in the basin and appears to come from the direction
o f t h e p r e s e n t Y u k o n d e l t a ; t h e Y u k o n , t h e r e f o r e , m a y h a v e supplied m o s t o f
the sediment in the sequence. A b o v e t h e u n c o n f o r m i t y , r e f l e c t i o n s a r e
extensive a n d p a r a l l e l , suggesting deposition over wide areas by unconfined
currents, like those that occur in a marine shelf environment.
Strong, discontinuous reflections from deep within Norton basin are inter-preted to be volcanic flows or sills. The volcanic rocks are apparently
concentrated deep in the grabens. If the volcanics are coeval with those on
St. Lawrence Island, they would have a Paleocene to Oligocene age.
40
Oil seeps have been reported around Norton Sound for many years; but none of —
these have been verified during recent surveys by U.S.G.S. geologists.e
Gas seeps commonly occur in and around Norton Sound. Two wells at Cape Nome
encountered shallow, high pressure gas. Seeps of combustible gas are common
on the Yukon delta where gas is often trapped bepeath river ice in winter;●
this gas may be marsh gas (methane) of biogenic orjgin. Fisher, 1979, reports
that craters mark large areas of the seafloor, and acoustic anomalies common-
ly occur in seismic data, and that gas may cause both the
anomalies. A gas seep, located 64 kilometers (40 miles)
contains mostly carbon-dioxide gas, but a small fraction of
is also present.
Hydrocarbon source and reservoir characteristics of strata
craters and the
south of Nome,
hydrocarbon gas
in Norton Basin
are inferred by Fisher, et al. (1979) from the characteristics of strata that
rim the basin, but which may not be,in or beneath the basins and from the
acoustic signature of the basinf ill.
3.2.2.3 Source Rocks
To determine the source potential of strata aropnd Norton basin, outcrop
samples from St. Lawrence Island, from the Sinuk River Valley on the -Seward
Peninsula, and from the Yukon-Koyukuk province were analyzed by the U.S.G.S.
f o r t h e r m a l m a t u r i t y a n d f o r
In nine outcrop samples from
to Tertiary, the Paleozoic
source richness.
St. Lawrence Island
and Mesozoic rocks
ranging in age from Devonian
showed herbaceous and woody
kerogen to predominate, which is indicative of a gas-prone environment.
Thermal alteration index values show all samples are thermally immature,
except for the sample of Permo-Triassic shale. The low thermal alteration of
the samples of P~leozoic rocks implies that these strata have not been deeply
buried under St. Lawrence Island. The sample of Permo-Triassic shale is the
one thermally mature sample, and the maturity may be attributed to local
thermal effects of Cretacreous intrusive.
●
●
●
41
Non-marine Tertiary strata on St. Lawrence Island are mostly
and siltstone that have high organic-carbon contents. The
coaly sandstone
predominance of
woody and coaly kerogen and ttre low degree of thermal alteration make these
strata possible sources for methane gas.
Geochemical analysis of non-marine Tertiary strata in the Sinuk Val”
indicate these sediments to be gas prone, as are outcrop shale samples
the middle Cretaceus deltaic strata exposed in the sea cliffs near
town of Unalakleet.
i ey
in
the
rim Norton basin results from the
deposition of the strata. If it is
The predominance of woody, herbaceous, and coaly kerogen in the gas-prone
Tertiary and Cretaceus strata that
non-marine and deltaic environments of
inferred that the same type of kerogen predominates in’ deltaic strata in
Norton basin, then gas-prone strata would be yielded here too. The descrip-
tion of strata as “gas-prone” does not mean oil cannot be generated and
produced; rather the description means gas is more likely to be produced than
oil. The marine strata above the regional unconformity in Norton Basin may
contain more amorphous kerogen than the deltaic strata, and may, therefore,
be a source for oil if the strata are thermally mature.
In the offshore area, some strata are
as shown by gas from the seep south
carbon dioxide, gasoline range (C5-C7)
in the gas indicate source strata of unknown quality are in the basin
mature enough to produce hydrocarbons
of Nome. Though most of the gas is
hydrocarbons that are present
The magnitude of the thermal gradient in the basin is another unknown
The extensional tectonics that formed the basin may have caused crusts’
attenuation beneath the basin and volcanism; this probably increases the
geothermal gradient in the basin over the gradient that exists outside
the area of extension. Rifted basins in other areas of the world generally
have high geothermal gradients which are preferred in the generation of
hydrocarbons.
3.2.2.4 Reservoir Rocks
Although the quality of reservoir rocks in Norton basin is unknown, some
assumptions can
reservoir strata
of the reservoir
be made based on regional paleogeography. The quality of
older than late Miocene may be dependent on the provenance
strata, i.e., the provenance may determine the percentage of
o●
quartz in the reservoirs. Since late Miocene time, the Yukon River has had
an enormous drainage area that has supplied quartz to Norton basin, as shown
by modern Yukon sediments that contain an avercge of 25 percent quartz.
Before the late Miocene, however, the proto-Yukon had a more restricted
drainage area, atid may have received a-large proportion of sediment from
Cretaceus strata in the Yukon-Koyukuk province, and strata in this province
contains only 8 percent quartz. Therefore, the reservoir potential of middle
Miocene and older strata in the Norton basin may be limited.
Seismic data show a delta of large areal extent in Norton basin that appears
to head at or near the present Yukon delta, suggesting a large portion of the
pre-late Miocene basin fill came from the Yukon. Sediment may also have been
introduced from quartzose sources on the Seward Peninsula. Accordingly,
reservoir quality may improve northward from the Yukon delta in strata older
than late Miocene= The deepest part of the basin, however, is adjacent to *the mouth of the Yukon. Reservoir quality m a y l o c a l l y improve b e c a u s e o f
sorting of the quartz-poor sediment by the proto-Yukoh River.
Another local source for basin fill are Paleogena volcanics that may have
reduced the reservoir quality of Paleogene strata by introducing chemically
reactive material, such as volcanic ash and tuff, that later turn to clay and
low grade metamorphic-minerals, impairing both porosity and permeability.
Migration
contain a
Traps of
of petroleum from Cretaceus or lower Paleogene strata strata
large volcaniclastlc component.
3.2.2.5 Traps -;.?
economic importance in Norton basin are closures produced by
●
●
potential sand reservoirs draped over pre-Tertiary “basement” horsts.
43
A significant criterion to consider in the tectonic evaluation of the
Norton basin is the timing of structural growth as it relates to time
of deposition of the host reservoir beds. Generally, in the productive
Teritary basins which rim the Pacific Margin, early structural growth or
development of synchronous “highs”, is essential for entrapment of large
hydrocarbon accumulations.. It is important to determine seismically if
structural growth can be demonstrated over the horst features of the Norton
basin.
3.2.3 U.S. Geological Survey Resource Estimates
The petroleum development scenarios described in this report are based
upon U.S. Geological Survey estimates of undiscovered recoverable oil and
gas resources of Norton Basin. The most recent estimates for Norton Basin
are presented in U.S. Geological Survey Open-File Report 79-720 (Fisher
et al., 1979). Two estimates are presented in that report.
95 Percent 5 Percent ~ StatisticalProbability Probability Mean
Oil (billions \of barrels) o 2 . 2 0.54
Gas (trillionsof cubic feet) o 2.8 0.85
These are risked probabilistic estimates to which a marginal probability is
assigned to the event that commercial oil and gas might be found since Norton
Basin is a frontier area with respect to petroleum exploration. The marginal
probabilities applied were 40 percent to oil and 60 percent to gas. Thus the
9.5 percent probability estimate. (above) is zero. For impact
purposes, the U.S.G.S. has defined alternate estimates as follows:
Minimum Mean Maximum
Oil (billionsof barrels) 0.38 1.4 2.6
Gas (trillionsof cubic. feet) 1.2 2.3 3.2
assessment
44 -
The ‘risked’ resource estimates presented by the U.S. Geological survey
(e.g. the estimates presented in Circular 725 are risked, estimates) are
made by applying a marginal probability to unconditional estimates. Risked
estimates reflect the possibility of oil or gas not being present and are
“*●
made for frontier basins for which little geologic data is available and
where no drilling may yet have taken place (Gordon Dolton, U.S. Geological
Survey Resource Appraisal Group, personal communication). Oil and gas
estimates are made independently. (For additional information on U.S.
Geological Survey Resource estimates the reader is referred to Circular ●725.) The scenarios jn this study are based on those unrisked estimates.
The area considered in the U.S.G.Si resource assessment is bounded by
latitude 63°00’ and 64*45’N and longitude 162°00’ and 170°00’W, an area
i n excess o f 4 0 , 0 0 0 sq. k i l o m e t e r s (15,444 sq. m i l e s ) . Sediment volume
in the assessment area is estimated at about 60,000 cubic kilometers (23,168
cubic miles).
3.2.4 Assumptions
Oi 1
Initia”
3.2.4.1 Initial Production Rate
well production rate is a parameter used n the economic analysis
and scenario formulation as an index of reservoir performance in the absence
of specific data on reservoir characteristics such as pay thickness, poros-
ity, permeability, drive mechanism, etc. initial productivity is a function
of such reservoir characteristics as pay thickness, porosity, and permeabil-
ity. T h e initial p r o d u c t i v i t y per well
h a v e t o b e d r i l l e d t o e f f i c i e n t l y d r a i n
Initial well productivities assumed for
influences the numbers of we’
a given reservoir.
this study are 1,000 bpd, 2
9
1s which
000 bpd,
O@
9
●
and 5,000 bpd. These have been selected, in part, on the basis of limited
●
45
geologic/analog data and, in part,
of economic senistivities related
consistent with the general ranges
by the requirement to explore a range
to this parameter. These values are
of reservoir performance for many of
the Pacific Margin Tertiary basins including Cook Inlet. R an analog, Upper
Cook Inlet initial well productivities have averaged 1,000 to 2,000 bpd
although there are some wells which have produced at significantly higher
rates, notably in the McArthur River field (Diver, Hart and Graham, 1976).
Currently, production from Cook Inlet oil fields is in decline. In 1977,
for example, wells were averaging for the individual fields from 159 bpd to
1,530 bpd (State of Alaska, Department of Natural Resources, Division of Oil
and Gas, 1977).
Five thousand barrels per day is the maximum sustainable rate realized
for the more prolific Pacific Margin Tertiary basins. Available geologic/
analog data imply that initial productivity below 2,000 bpd well is much
more likely than initial productivity in the 5,000 bpd well range.
In previous scenario studies for the northern Gulf o,f Alaska and western
Gulf of Alaska (Kodiak Tertiary basins), we assumed an initial well produc-
tion rate of 2,500 bpd but evaluated limited cases of 7,500 bpd (regarded as
unlikely). These are both Pacific Margin Tertiary basins. In Cook Inlet,
which is a Tertiary basin but also has Mesozoic prospects in its southern
part (Lower Cook Inlet), 1,000, 2,000, and 5,000 bpd initial well productiv-
ities were assumed -- the same productivities assumed for this study.
Non-=Associated Gas
Initial productivity per well for non-associated gas is assumed to be 15
nrncfd based on the Teritary analog of Upper Cook Inlet. Upper limit produc-
tivity is assumed to 25 mmcfcl for field size sensitivity testing,
3.2.4.2 Reservoir Depth
Three reservoir depths have been assumed for this study --= 762, 1,524
and 2,286 meters (2,500, 5,000 and 7,500 feet) -- for both oil and gas
prospects.
46
Review of very limited seismic data covering only a portion of the Norton
basin indicated sediment thicknesses generally thinner than 3,048 meters
(10,000 feet) and more commonly less than about 1,981 meters (6,500 feet
over the horsts; the thickest basin fill is located in the intervening
grabens. If the sediment thickness indicated in the sample are over the
horsts (structurally, the potential Norton basin traps are closures produced
by potential sand reservoirs draped over these pre-Tertiary basement horsts)
then shallow reservoirs (i.e. <1,524 meters or <5,000 feet) predominate.
Reservoir depths selected for analysis in this study are, therefore in the
shallow to medium range as follows: 762 meters (2,500 feet), 1,524 meters
(5,000 feet) and 2,286 meters (7,500 feet).
Reservoir depth in this analysis is a parameter which defines the number of
platforms required to efficiently produce a given field size. All other
factors being equal, a shallow field with a thin pay reservoir covering many
square kilometers and requiring several platforms to produce is less economic
than a field of equal reserves, with a deep, thick pay zone, which can be
reached from a single platform. In the economic analysis and scenario
detailing, reservoir depth dictates the rate bf development we?l completion
which in turn effects the timing of production start-up and peak production
(and the schedule of investment return). The well completion rate also
affects’the development drilling employment.
3.2.4.3 Recoverable Reserves
It can be shown that reservoir characteristics -- porosity, permeability,
connate water, driving mechanism; and depth as it relates to pressure,
etc. -- together with thickness of payzone define the recoverable reserves
per acre. Thus , recoverable
of more technical functional
wells required to produce a
Recoverable reserves are also
(of pay). Multiplying the pay
reserves per acre. For most
reserves per acre is a good proxy in place
relationships for determining the number of
field, given its initial production rate.
commonly expressed as barrels per acre foot
thickness by bbl/acre foot gives recoverablePacific Margin Tertiary basins, including *o
●47
Cook Inlet, recoverable reserves per acre can generally be bracketed between
20,000 and 60,000 bbl; assuming a recovery factor of 200 bbl/acre foot pay
thicknesses would be 30 meters (100 feet) and 91 meters (300 feet) for these
recoverable reserves respectively.
Higher recovery factors such as those now foun~ in the Jurassic of the
North Sea, the Permo-Triassic of the North Slc’pe of Alaska and Crete-
ceous sand reservoirs af,the Middle East cannot be used as a basis for
comparison. The reservoirs in these basins are generally mineralogically
different than those in pacific Margin Tertiary basins. The Tertiary
sand reservoirs are typically arkosic with significant percentages of
unstable feldspar minerals which cfiagenetically alter the clay minerals,
thus reducing porosity and permeability. Sand reservoirs in the North
Sea and North Slope, however, consist of high percentages of stable minerals
such as quartz and have high porosities and perm~abilities and correspond-
ingly high productivities.
An assumption on a range of recoverable reserves pe- acre is requiied inthis
study as a general indication of the potential a rein extent of a field for a
given (assumed) reserve or field size assuming simple reservoir geometry.
This assumption in combination with reservoir depth (see Table 3-1) and well
productivity, allows an estimate to be made of the number of platforms
required to drain a given field. A “best case” platform spacing is assumed
in so far as the reservoir geometry is assumed to be a simple anticline.
Obviously, a complex faulted reservoir with the same reserves will necessi-
tate a different platform configuration, more platforms or even the use of
subsea wells. Subsea wells may be required in a complex reservoir to drain
islolated portions of a reservoir that could not be reached from direction-
ally-drilled wells from a p?atform if the incremental recovery could not
economically justify investment in an additional platform.
Technical Discussion
A brief technical overview of estimating recoverable reserves will demon-
strate the complexity of the problem and the requirement for much more
.
..-
TABLE 3-1
MAXIMUM AREA ~HICH CAN BE REACHED WITHDEVIATED WELLS DRILLED FROMA SINGLE PLATFORM
.
DeDth of Reservoir I Maximum Area PrnducpdMeters
762
1,525
2,286
3,050
3,812
4,575
Feet Sqe Mile;I
2,500 1.0
5,000 3.0
7,500 7.0
10,000 12.5
12,500 19.5
15.000 28.0
Acres
640
1,920
4,480
8,000
12,480
17,920
.--—Hectares
259
777
1,813
3,238
5,051
7,252
Notes:
1. Maximum angle of deviation assumed to be 50 c:egrees.
Source: Dames & Moore
●
●
●
ao
)detailed reservoir data than is presently available for the Norton
Basin.
Recoverable oil from a reservoir is controlled by a combination of the
following parameters:
o
0
e
a
o
@o
0
*
9
Oil gravity
Oil viscosity
Gas volubility in the oil
Relative permeability
Reservoir pressure
Connate water saturationPresence of a gas cap, its size, and method of expansion
Fluid production rate,.
Pressure drop in the reservoir
Structural configuration of the reservoir
I Many studies have been made of the relationship between these parameters,
most of which are statistical in nature.
It should be clearly understood that any prediction
or recovery factor, is very difficult to evaluate,
be a matter of judgement based on available data
reservoirs of a comparable nature.
of recoverable reserves,
and usually winds up to
and analogy to existing
In a study for API (Arps, 1967) and a subsequent paper by the same author
(Arps, 1968) J.J. Arps presents a “formula” approach for calculating the
recovery factor for solution gas drive and water drive reservoirs. The
formula also gives tabulated ranges of recovery factors for solution gas with
supplemental drive, gas cap, and gravity drainage reservoir drive mechanisms.
In order to use the formula, a knowledge or estimate of the following data is
needed:
s Porosity
c Water saturation
o Oil information volume factor
50
e Permeabi 1 ity
e Oil and water viscosities
● Initial and abandonment pressures.
It should be noted that in order to calculate recoverable reserves in
barrels an estimate of both reservoir thickness and area? extent is needed. ●
Probably the most difficult question to answer in estimating recovery factors
is what is the effect of production rate. The answer to this is based on the
relative permeability effects, and they are very complex. Arps’ studies do*
not take this into account because of the lack of data on relative perme-
ability.
3.2.4.4 Well Spacing
General Considerations and Oil
Well spacings consistent with industry practic~ and varying as a func-
tion of initial well productivity and recoverable reserves per acre are
implicit in the scenarios. For shallow reservoirs, industry well spacing
practices can restrict the number of wells drilled from a platform and
this has economic impact on the field development decision.
The number of wells that can be drilled from a platform depends on:
o Reservoir characteristics of the particular oil or gas field.
e The average depth of the reservoir.
The first item governs how the oil or gas flows. We have fixed initial
production rates by assumption (Section 3.2.4.1). Reservoir depth determines
the maximum area which can be produced from a platform, assuming that a
deviated well can be drilled to an angle of up to 50 degrees from the verti-
cal; Table 3-1 shows that the maximum area that can be produced from a single
platform ranges from (640 to 17,920 acres), assuming the depth ranges from
762 to 4,572 meters (2,500 to 15,000 feet). For the assumed reservoir depths
of this study, a stngle platform will be able to reach a maximum area of
either one square mile (640 acres) for a 702 meter (2,500 feet) deep reser-
voir or seven square miles (4,480 acres) for a 2,286 meter (7,500 feet) deep
reservoir.
Using industry
for the Norton
per well as a
practices in
basin fields
function of
the Upper Cook inlet as an analog, well spacing
should range, therefore, between 80 to 320 acres
initial well productivity and re-cover able re-
serves per acre. The oil wells in McArthur River field in Upper Cook Inlet,
for example, are now complete with an 80 acre spacing. Although the original
spacing was 160 acres, this subsequently has been reduced by in-filling as
field development proceeded. Depending therefore, on reservoir depth,
initial productivity, and the number of wells per platform, sufficient
platforms will be assumed to house enough wells to:
e Allow spacing between 80 to 320 acres.
@ Al?ow exhaustion of recoverable reserves within 20-25 years.
With a 762 meter (2,500 feet), reservoir depth, 80-acre spacing implies
no more than 8 wells may be drilled into a reservoir from a single platform.
Forty wells may be drilled into a reservoir at 2,286 meters (7,500 feet).
This implies 112 acre spacing.
Non-Associated Gas
As noted in the Lower
well spacing in Alaska)
Cook Inlet scenario study, (Dames & Moore, 1979c)
frontier areas is likely to be set by the market
.
demand for gas, rather than by industry desire to maximize recovery.
Consistent with reservoir engineering and petroleum geology constraints,
well spacing up to 518 hectares (1,200 acres) may allow sufficient gas
production to run potential LNG capacity. Final design well spacing in
the usual U.S. range of 160 to 320 acres may have little relevance to gas
producers in the Norton basin if they have no market for their gas. The
onshore Kenai gas field in Upper Cook Inlet, however, which has long-term
contracts with both domestic and industrial users in the Cook Inlet area,
is currently developed with wells on a 320 acre spacing.
Traps of
potential
indicated
3.2.4.5 Field Sizes and Field Distribution
economic importance in Norton basin are
sand reservoirs draped over per-Tertiary
closures produced by
basement horsts. As
in Section 3.2.1, good quality seismic data is required to identify
and rate prospective structures in an untested province such as Norton basin.
o●
If the assumption is made that offshore Norton bas~n traps will be hydrocar-
bon bearing, and assuming seismic data is available to identify structures
and estimate the areas of closure, etc., the all Important economic problem
~s predicting percent fill-up (percent of geological closure or reservoir
unit within geological closure that is filled with hydrocarbons). The
approach used to predict fill-up is an analogy based on statistical compari-
sons with known productive Pacific margin basins. It should be emphasized,
however, that any analogy based on statistical comparisons with known pro-
ductive Pacific margin basins. It Should be emphasized, however, thate
any analogical approach to prediction of petroleum resources is extremely
hazardous in that each basin is unique. One critical difference in geologic
parameters can completely negate the effect of many similarities.e
Factors effecting percent fill are the richness of the source rock and
quality of reservoir. In addition, trap density is a~so an important
factor. Generally, the greater the trap density, the smaller the fill-up.
As examples, the average percent fill-up of productive closures in thePacific Margin Los Angeles and Ventura basins are 40 percent and 15 percent,
respectively.
Qo
53
Unfortunately, there is no reliable way to rationally estimate percent
fill-up in Norton basin. Based on data from around the Pacific Margin,
we assume that fill-up in excess of 50 percent wou?d be the exception
in Norton basin. In estimating potential reserves of this basin, only
those areas lying within the 50 percent fill contour should be considered,
with 25 percent fill-up considered as average.
In the absence of sufficient geologic data to make reasonable predic-
tions on the number of prospective structures and field sizes that may
be discovered in Norton basin, the field sizes selected for economic screen-
ing have therefore been selected to be consistent with the following factors:
o
0
@
e
U.S. Geological Survey resource estimates (Fisher, et al., 1979).
Anticipated economic conditions (based on economic studies of
other offshore areas).
Geology (only gross structural geology and stratigraphic data
are available).
Requirement to examine a reasonable range of economic sensi-
tivities.
The field sizes to be evaluated in this study, therefore, range from 100
million barrels to two billion barrels for oil and 500 billion cubic feet to
(1) The maximum fieldthree trillion cubic feet for non-associated gas.
size is determined by the total resource estimate assuming that the total
resource is contained in a single field (a most unlikely occurrence).
3.2.4.6’ Allocation of the U.S. Geological Survey Gas
Resource Estimate Between Associated and
Non-Associated and Gas-Oil Ratio (GOR~
1Prediction as to hydrocarbon type, (oil versus gas which may be encoun-
tered), is extremely difficult to assess in the Norton basin. Based on
54
meager and scattered outcrop data along the onshore perimeter of the basin,
F i s h e r , e t a l . , ( 1 9 7 9 ) , b e l i e v e t h e o f f s h o r e N o r t o n p r o v i n c e t o b e g a s - p r o n e
rather than o i l . Our petroleum geologist suggests that this conclusion be
viewed with extreme caution, as the Cretaceus and older onshore rocks which,.. were analyzed for source
basement in the offshore.
Tertiary basins which also
rock potential, probably constitute effective
There are no known productive Pacific Margin
have significant amounts of producible hydrocar-
bons from pre-Tertiary rocks.
Review of producing Pacific Margin Tertiary basins does not provide meaning- 9
ful analogs for the Norton
the type of natural gas and
The U.S. Geological Survey
basin since these basins present a wide range in
gas-oil ratio (GOR).
estimates do not specify any
to non-associated gas resources and no such ratio is
estimates. If the Norton basin is gas-prone, as the
then a significant portion of the gas resources cart be
associated.
ratio of associated
implicit in their
U.S.G.S. contends,
assumed to be non-
In the northern Gulf of Alaska petroleum development scenarios study (Dames &
Moore, 1979a), the assumption was made that 20 percent of the gas resource
was associated and 80 percent was non-associated following an assumption made
in a report by Kalter, Tyner and Hughes (1975) based on U.S. historic produc-
tion data. In the Lower Cook Inlet scenario study (Dames & Moore, 1979c).
The assumption was made for scenario detailing and analytical simplification
that all the gas resource was non-associated (i.e., scenarios were formulated
which included gas fle?d(s) totaling the U.S. Geological Survey gas resource
estimate). In reality, however, some portion of the gas resource will be
associated; the Lower Cook study implicitly assumed that the oil fields are
9
characterized by a
the platforms with
The treatment of
1 Ow
the
the
gas-oil ratio (GOR) and that the gas was used to fuelaremainder reinfected.
associated/non-associated problem in the analysis
is critics because in Alaska offshore frontier areas, non-associated gas
559
resources, in many locations, are less economic than the same amount of
associated gas. This is because the incremental investment to produce
associated gas (with oil the primary product) is less than the total develop-
ment costs for a non-associated gas field with the same recoverable reserves.
In this study, as with Lower Cook Inlet, we assume that all the gas is
non-associated, (i.e., scenarios are formulated which include gas fields
totaling the U.S. Geological Survey resource estimate). This assumption
is not inconsistent with the possibility expressed by the U.S.G.S. that
Norton is gas prone (U.S. historic production data indicates that 80 percent
OT the U.S. gas resource is non-associated.) With this treatment of the
associated gas/non-associated gas problem, the scenarios will assume oil
fields with a low GOR and no production to market of associated gas; associ-
ated gas is assumed to be used to fuel the platforms and the remainder
reinfected. It should be noted that this assumption will increase the
Inumber of fields (and hence equipment requirements -- platforms, pipelines,
etc.) over a scenario that assumes a significant proportion of the gas
reserve is associated and produced incrementally with oil.
There is no available data to provide a firm basis on which an assump-
tion can be made on the gas-oil ratio (GOR) in hypothetical Norton basin
reservoirs. GOR can vary considerably from field to field in the same
basin and between different reservoirs in the same geologic horizon.
Initial GOR in upper Cook Inlet fields, for’ example, ranges from 65 to
1,110 standard cubic feet (SCF) per barrel (Magoon, et al., 1978).
3.2.4.7 Oil Properties
There is no data to predict the quality of oil that may be found in the
Norton basin although many of the producing Pacific Margin Tertiary basin
fields produce low sulphur, medium to low gravity (medium to high API num-
bers) crudes.
-.
●
The gravity of oil in upper Cook Inlet fields, for example, ranges from 27.7
degrees API (shut in Redoubt Shoal field) to 44 degrees API. Sulphur content●
is generally low with a maximum of 0.22 percent in the Redoubt Shoal field
(shut in).
The uncertainty relating to the characteristics of crude that may be discov-
ered is reflected in the range of prices assumed in the analysis (Section
3.4.3.3).
3.3 Technology and Production System Selection
Having defined the reservoir and production parameters to be evaluated
in the economic analysis, the next step in the scenario development process
and economic analysis is the selection of production systems to be screened
in the economic analysis. This selection, which is central to the study,
involves:
@
e
o
●
o
Identifying production systems and transportation options suitable
for the oceanographic conditions of Norton Sound and most likely to
be adopted by industry for this region.
Estimating costs
forms, pipelines,
for the various components of the systems (plat-
ter’minals, etc.)
Matching petroleum engineering with representative reservoir
conditions (reserves, reservoir depth, recoverable reserves
per acre, initial well production rates).
Scheduling field development investment
Identifying construction schedules for
components for employment estimation.
fl Ows .
various production system
●
57
As indicated in Appendix C, ice reinforced steel platforms of a modified
Upper Cook Inlet design will probably be the most favored platform option.
Ice conditions may not be sufficiently severe to require more exotic struct-
ures such as the monotone or cone. Integrated barged-in deck units may be
utilized to reduce offshore construction time due to the short summer weather
window.
In the shallower waters of the Norton Sound (<23 meters [75 feet]), depending
upon gravel availability and environmental sensitivity, gravel islands and
caisson-retained gravel islands may be technically feasible. Modularized
barge-mounted process units, ballasted down and surrounded by gravel berms or
caissons may be the favored engineering strategy for gravel or caisson-retain-
ed production islands.
Economic evaluation of field development not only involves identification of
platform types but also transportation requirements including pipeline
specifications and shore terminal requirements and some assumption on discov-
ery location..,
As discussed in Appendix D, five potential sites have been identified
for location of a crude oil terminal and/or LNG plant in Norton Sound
and adjacent portions of the Bering Sea: Capt Darby, Cape Nome, Nome,
Lost River, and Northeast Cape (St. Lawrence Island). Having established the
location of these potential terminal sites, identification of representative
discovery locations (in the absence of site-specific data on geologic struct-
ures), permits estimation of maximum, minimum, and average potential pipeline
distances (offshore and onshore) to the closest suitable terminal site for
economic screening; these are summarized in Table 3=-2.
3.4 Summary of Field Development Cases for Economic Evaluation
Each field development case evaluated in the economic analysis has the
following components (see Figures 3-1 and 3-2):
o Reservoir characteristics.
-.
. . . . .
9 Engineering strategy (type of platform, numbers of platforms,
pipeline requirements, etc.) which is dependent on the reservoir
characteristics, oceanographic conditions, and discovery location
relative to shore terminal s~tes.
@ Oceanographic setting (water depth, ice conditions, etc.).
* Geographic location (distance to shore and terminal sites and
related logistic constraints).
These components are summarized in Tables 3-2, 3-3, and 3-4. Since there are
too many combinations of these parameters to meaningfully evaluate within the
time or budgetary constraints of such a study:, some selectivity in cases to
be analyzed is required. This selectivity involves identification of the key
geologic, engineering, and geographic problems affecting the economics of
field development in the Norton Sound area. Consideration of the reservoir,
engineering, oceanographic, and geographic components summarized in Tables
3-2 through 3-4 led the study team to explore the following field developmentw
problems or issues:
Economic sensitivity of initial well production rates.
The effects of shallow reservoirs on field development economics.
Sensitivity of field development economics to pipeline distance.@
Impact of water depth on field development economics.
Sensitivity of field development economics to delays caused by
weather conditions, environmental constraints, or technology
p r o b l e m s .
●
59
TABLE 3-2
REPRESENTATIVE PIPELINE DISTANCES TO NEARESTTERMINAL SITE EVALUATED IN ECONOMIC ANALYSIS
Pipeline LengthWater Depth of Field Offshore Onshore
Case meters (feet) kilometers (miles) kilometers (miles) I
No. 1 15 (50), 30 (100), 46 (150) 128 (80) 3 (2)
No. 2 15 (50), 30 (100), 46 (150) 64 (40) 3 (2)
No. 3 15 (50) 32 (20) 48 (30)
No. 4 15 (50) 32 (20) 3 (2)
No. 5 15 (50) 16 (10) 3 (2)
Note: Both shared and unshared pipeline cases are screened in the economic analysis.
Source: Dames & Moore
tm
.
TABLE 3-3
SUMMARY OF RESERVOIR CHARACTERISTICSEVALUATED IN THE ECONOMIC ANALYSIS
Field Sizes: oil (Mmbbl ) - 100, 200, 500, 750, 1,000Gas (tlcf) - 1,000, 2,000, 3,000
Recoverable Reserves Per Acre: Oil (bbl) - 20,000, 60,000G a s (mmcf) - 120, 300
Initial ldell Production Rates: Oil (bpd) - 1,000, 2,000, 5,000G a s (mmcfd) - 15,25
Reservoir Depths: Meters (feet) - 762 (2,500), 1,524 (5,000) , 2,286 (7,500)
Source; Dames & Moore
o● ● ● *
Q● ●
PRODUCTEVALU
TABLE 3-4
ON PLATFORMS AND MATER DEPTHSED IN THE ECONOMIC ANALYSIS
Water Depth IPlatform Type meters feet
Ice reinforced steel platform 15 50(modified Upper Cook Inlet Design) 30 100
46 150
Gravel Island 7.6 2515 50
Source: Dames & Moore
Q Evaluation of “giant” field ecofiomics and sensitivity of a number
of platforms required to develop a field.
e Evaluation of gravel island economics.
Evaluation of these economic sensitivities requires that some of the field
development components remain constant. For example, to test water depth
sensitivity, requires that the pipeline distance remain constant. To test
reservoir depth sensitivity, for example, requires that other reservoir
parameters and pipeline distance be fixed.
The selection of cases for economic analysis also involves sequencing
of cases to define the major economic/non-economic boundaries of various
field development situations f~rst so that the analysis is meaningfully ●
structured to avoid waste of analytical dollars. For example, reservoirs
permitting 1,000 b/d wel 1s are screened prior to those with 2,500 b/d
and 5,000 b/d wells since 1,000 b/d wells are an obvious adverse economic
condition. *
3.5 Economic Analysis
3.5.1 Role of the Economic AnaJysis in Scenario Formulation
In the scenario formulation process the economic analysis identifies those
production systems which are economic and the minimumffeld sizes required to
justify development for various discovery locations and production systems.
The results of the economic analysis also indicate the impact of various
reservoir characteristics (depth, productivity potential, etc.) upon the
economics of field development.
The primary role of the economic analysis in the scenario development
process is to:
.
●
●
●63
. .
t
e
o
0
0
Identify a minimum field size for development in relation to
various physical characteristics that may be associated with
different discovery locations.
Identify the relationship between water
for a given field size.
Identify the most economic production
field size and discovery location.
depth and field development
system option for a given
Specify the general reservoir characteristics that would have to be
encountered for a given field size in a specified location to
justify development.
Identify the minimum required price for development of a field with
specified characteristics.
3.5.2 The Objective of the Economic Analysis
The objective of the economic analysis is to evaluate the relationships among
the likely oil and gas production technologies suitable fbr’ conditions in
Norton Sound and the minimum field sizes required to justify each technology
as a function of geologic conditions in different parts of the Sound.
The analysis of this report will focus attention on the engineering technol-
ogy required to produce reserves under the difficult conditions of the Norton
Sound and will emphasize the risk due to the uncertainties in the cost of
that technology. Sensitivity and Monte Carlo procedures will be used in the
analysis to allow for the uncertainty in the costs of technology and the
uncertainty in the price of the oil and gas.
A model has been formulated that will allow determination of either:
(a) the Minimum Field Size to justify development under several oil and
gas production technologies, or (b) the Minimum Required Price to justify
development given a field size and a selected production technology.
64 -
The model is a standard discount cash flow algorithm designed to handle
uncertainty among key variables and driven by the investment and revenue
streams associated with a selected production technology. The essential
profitability criteria calculated by the model are: (a) the net present
value (NPV) of the net after tax investment and revenue flows given a
discount rate, or Value of Money (r) and, (b) the internal rate of return
which equates the value of all cash flows when discounted back to the
initial time period.
. eIn the following sections, the mode?, its assumptions, and their implica-
tions are discussed.
3.5.3 The Model and the Solution Process
3.5.3.1 The Model
The Model calculates the net present value of developing a certain
field size with a given technology appropriate for ~ selected water
distance to shore. The following equation shows the relationships
variables in the solution process of the model.
9
depth and
among the
Equation No. 1: NPV = [Price x Production x (1 =-Royalty) - Operation Costs 2 ●
(l-Tax) + [Tax Credits ]- ~Tangible Investments + Intangible Costs]] x PV
where: NPV
Pv
= net present value of producing a cer- ●
tain field with specified technology
over a given time period.
= present
discount
money, r
value operator to continuously
all cash flows with value of
65
●
Price
Production
.
Royalty
Operating Cost
Tax
Tax Credits
TangibleInvestments
IntangibleInvestments
wellhead price
= annual production uniquely associ-
ated with a given field size, a
selected production technology, and
a number of wells
royalty rate
annual operation costs
tax rate
= the sum of investment tax credits
(ITC) plus depreciation tax credits
(DTC) plus intangible drilling
costs tax credits (IllC)
= development investments
over life of production
depreciated
= development expenditures that can
be expensed for tax purposes.
The model does not include exploration costs or an allowance for a bonus
payment. The model assumes discovery costs are sunk and answers the ques-
tion, “What is the minimum field size required to justify development from
the time of discovery given a selected production technology?”. “Sunk”
exploration costs -- seismic and geophysical, dry hold expenditures, andlease bonuses -- must be covered by successful discoveries.
66
..-.— -
This aumes that these costs which are not small, are covered
by thelings from its successful portfolio of exploration irtvest-
ments (
The moct include a term for salvage or equipment at the end ofproductssumption is made that the cost of removal of all equipment
and of the producing area to its pre-development environmental
conditit state and federal regulations would be as much as the
Salvage:he equipment. The model assumes that the cost of removal @
will bethe value of the salvage.
Solution
●
Equatiorn be solved deterministically if values for the critical
variabl~n with reasonable certainty. But single values for the
indepen~es on the right-hand side of Equation No. 1 are not known.
The teckhat have been developed for the Beaufort Sea and Canadian
Arctic, the cost estimates have been made, have not been tested inthe Noi@nd/or cost-estimated in the United States. Thus, upper,
lower, age values have been estimated for the critical variables of
Equation are used in the solution process.
The ~od~so~ved given field size, prices, and a selected tech-
nology fie of return that will drive the
-Sensitiviis can be used to show how the
of returwith different values for:
●
●
NPV of production to zero.
previously calculated rate e
@ ng costs.
(1) Asslt “sunk” costs are covered by the successful portfolio of eexploratittment implies t h a t . t h e u p s t r e a m operat’ioris of verticallyintegrate~es must account for their profit and loss without reliance oon downstnings. For non-vertically integrated exploration and pro-duction ccthere is no alternative.
●
67.—___ — —
# Tangible investment costs.
@ Intangible drilling costs.
Iterative solutions of Equation No. 1, given prices and a selected technol-
ogy, can be used to determine the minimum size field to justify. development
at various values of money. Sensitivity analysis can be used to show how
changes in the values for the four items above change minimum economic field
size.
3.5.4 The Assumptions
3.5.4.1 Value of Money
.
The minimum field size calculation is extremely sensitive to the value
of money, r, used to discount the cash flows in Equation No. 1. Dames &
Moore has specified that 10-15 percent brackets the “real” rate of return
after tax in constant 1979 dollars that winning bidders will be willing
to accept to develop a field.
In consultation with BLM eco~omists and major oil ;ompany economic analysts,
it appears reasonable that 10-15 percent in constant 1979 dollars will
bracket most company hurdle rates for development of a given field in thet*i
Norton Sound~4).
10-15 percent in
current dollars.
3.5.4.2
The analysis is
sumption implies
(1) In Appendixbetween 10 and 15
Notice that if inflation is eKpected to be 8 percent,
constant dollars is equivalent to 18.8-24.2 percent inThis assumption follows the precedent of our prior studies.
Inflation
constructed in 1979 dollars.
that the existing relationship
A we provide solutions based on
This c o n s t a n t dollar as-
b e t w e e n p r i c e s a n d c o s t s
a ranqe of discount ratespercent but emphasize 15 Dercent in discussions because we
believe that to be ’c?oser to industry practices than 10 percent.
68
will remain constant, that oil and gas ’prices and the costs of their exploit-
ation will inflate at the same rate between now and the period of exploration
and development in the 1980’s. From 1974 to mid-to-late 1978, however, the
costs of finding and producing oil has risen faster than oil prices as shown
by Table 3-5. Alaskan costs (for which we have no index) have risen at a
faster rate according to industry sources.
Since the reduction of Iranian production in late 1978, world oil prices have
o●
risen faster than costs.
OPEC price inflation may
rise at a more or less
occur. Thus, we assume
economic determinations,
levels--is the important
This trend may continue for several years or this
create a general inflation that will cause costs to
equal rate. We cannot predict which scenario may
prices and costs fixed at their 1979 levels. For
the ratio of prices and costs--not their absolute
parameter. *
If prices rise faster than costs then the minimum field size will be smaller
than estimated. If, on the other hand, costs rise faster, then the minimum
field size will be larger.
3.564.3 Oil Prices
World Market
meeting during June, (1979) OPEC benchmark Arabian 1 ightAt the Geneva
crude went up to $18.00/barrel from the $14.54 established in March. The
other members of OPEC agreed to a ceiling of $23.50 through the end
1979. Under this pricing system, Iranian light, which is very similar
Arabian light, is selling at $21.22.
of
to
(1) Our economtc analysis was conducted prior to themeeting in Venezuala which failed to reach agreement onto the December pre-OPEC meeting price increases led byNorton Basin oil and gas marketing study (Appendix 1),after completion of our econom~c analysis, provides more(January, 1980) on OPEC oil pricing.
December 1979 OPECoil price and priorSaudia Arabia. Ourwhich was conductedcurrent information
. .69
— -
Annual
L-Rate ofGrowth:
TABLE 3-5
U.S. AVERAGE OIL AND GAS PRICE AND PRODUCTIONCOST INFLATION SINCE 1974
Year
1974
1975
1976
1977
1978
Oi 1 Gas IPAA DrillingPrices’ Pricesz Cost Per Foot3
100 I 100 100
116 138.9 114.9
119.8 188.3 124.6
130 266 137.3
141.0 310.2 155.0
1974-78 9.0% 32.7% 11.6%
Source: Dames “& Moore
Oil FieldMachinery& Tools”
100
124.4
137.9
149.9
164.5
13.2%
‘ BLS, Producer Price Index, 0561z BLS, Producer Price Index, 0531‘ IPAA, Annual Survey of Costs‘ BLS, Producer Price Index, 1191
Alaskan crude oil prices are linked to the world market. Essentially, a
refiner can choose to take an incremental cargo of either Alaskan crude or
OPEC crude depending on the economics at the time of his decision.
California and Hawaiian refiners are running about 875,000 B/D of North
Slope crude as their incremental crude above a base load of Californian and
Indonesian crudes. California clean air requirements impose very stringent
sulfur emission standards which require low sulfur fuel oil ,in order that
they be met. About 400,000 B/D of sweet Indonesian crude is required to meet
the state fuel oil demand.
North Slope crude beyond 875,000 B/D currently is shipped either to the Gulf
Coast or to the Virgin Islands to Hess’s large refinery. According to PIW,
companies hope to get upt o 950,000 B/D by the time the pipeline throughput ●
increases to 1.4 million B/D later this year.
Incremental Alaskan crudes from some future discovery say, in the Norton
Sound, would exceed West Coast capacity and would move to the Gulf Coast
of the United States--unless, of course, its sulfur content was very low
and it could replace the Indonesian imports.
In the following analysis the assumption is made that incremental Alaskan
crude must compete on the Gulf Coast with either Arabian light, Iranian
light, or Mexican crude.
Table 3-6 shows that the landed value of Iranian and Arabian crude on the
Gulf Coast is between $20.00 and $23.25/Bf3!..
The Mexican crude comparable to Arabian and Iranian light is called Isthmus.
Price F.O.B. Tampico is $22.60 with the short haul to the Gulf Coast, this
will lay-in at about $23.00. One of these crudes is the likely incremental
crude for a refiner on the Gulf Coast. A b a r r e l o f A l a s k a n crude must
compete with one of these.
●
☛
●
71
The Link to Alaska
Incremental Exxon and Sohio North Slope crude is shipped largely in 100-15OM
DWT U.S. flag tankers to the Northville
then transshipped in 40-50 M DWT tankers
Gulf Coast. Depending on freight rates
rently $1.34 ton or about $0.18 BBL--but
ship of the canal later fn 1979--cost of
Industries terminal in Panama and
through the canal to ports on the
and the canal toll, which is cur-
going up when U.S. gives up owner-
shipping Alaskan North Slope crude
from Valdez to the Gulf Coast is about $3.00 BBL.
Assuming that a barrel of Alaskan crude replaces either a barrel of Isthmus,
Iranian light or Arabian light on the Gulf Coast and that the quality differ-
ential between the crudes is $0.50, Table 3-7 shows that North Slope crude is
worth between $16.50 and $19.75 at Valdez.
North Slope crude destined for Los Angeles is worth about $2.00 a barrel
more in Valdez than incremental crude shipped to the Gulf Coast.
If some west-to-east pipeline existed, the oil could get to the Gulf Coast or
Midwest for about $0.75 barrel instead
canal. In this case, Alaskan North Slope
and $21.00 in Valdez.
Norton Basin Crude We?l-tiead Value (1)
Any discovered crude in the Norton Sound
of the $2.00 to ship through the
crude would be worth between $19.75
will experience expensive shipping
costs to clear the ice bound areas of the northern Alaskan coastal zone, may
have vastly different refining properties than Alaska North Slope crude, and
may replace imported oil with higher “real” prices than the current upper
limit of $19.75 for Iranian light, for instance, low sulfur $umatran light
which would lay into the west coast for about $23.00.
(1) Our economic analysis was conducted prior to the December, 1979,OPEC meeting in Venezuala which failed to reach agreement on oil pricesand prior to the December pre-OPEC meeting price increases led by SaudiArabia. Our Norton Basin oil and gas marketing study (Appendix F), whichwas conducted after completion of our economic analysis, provides morecurrent information (January 1980) on OPEC oil pricing.
--
TABLE 3-6
LANDED VALUE OF ARAi31AN AND IRANIAN LIGHT CRUDES{l)
$18BL
Iranian Light
Iranian Light, F.O.B. Kharg Island 21.22
Freight: to Bahamas (VLCC) MS 45 1.04
Transship Fee .20
Freight: Bahamas to U.S. Gulf Coast (60M DWT) WS 75 .33
Loss Allowance
VALUE OF CRUDE
Arabian Light
Arabian Light,
(1% of Cost and Freight) . 4 6
LAID-IN $23.25
F,O.13, Ras Tanura 18.00
Freight and Loss Allowance to U.S. Gulf Coast 2.00
VALUE OF CRUDE LAID-IN $20.00
*
Source: PIW (various issues); Platt’s Oilgram (various issues).
●(~) our economic analysis was conducted prior to the December, 1979, OPECmeeting in Venezuala which faiJed to reach agreement on oil prices and priorto the December pre-OPEC meeting price increases led by Saudi Arabia. OurNorton Basin oil and gas marketing study (Appendix F), which was conductedafter completion of our economic analysis, provides more current information(January 1!380) on OPEC oil pricing.
e
73
There is a great deal of uncertainty about how crude from the frozen north-
west of Alaska’s OCS would be transported to market--or how much it would
cost. A 1977 northwest Alaska tanker transportation study conducted for the
U.S. Department of Commerce (Global Marine Engineering Co., 1977) indicated
that one transportation option was crude shipment in specially designed
ice-reinforced shuttle tankers that would take northwest Alaska crude to a
terminal in the Aleutians such asDutch Harbor. There it would be trans-
shipped to conventional tankers for transport to either the West Coast or
Gulf Coast. Cost of this is estimated to be between $2.00-$2.50/BBL to the
West Coast, or about $1.10-$1.60 more than the $0.90 shipping cost from
Valdez to the West Coast. These are very speculative numbers.
Adjusting the value of North Slope crude on the Gulf Coast shown on Table 3-7
by this $1.10-$1.60 differential’ indicates that some Norton Sound crude
replacing incremental Isthsmus or Iranian crude would be worth between $18.15
to $18.65 at the well head. As a replacement for Arabian Light, some Norton
Sound crude would be worth $14.90-$15.40 at the well-head. If it were a low
sulfur crude and could replace Sumatran light on the West Coast, it would be
worth between $20.50 and $21.00 at the well-head in the Norton Sound.
.
For this analysis we have pegged the lower, mid, and upper well-head values
for the Monte Carlo analysis for Norton basin crpde at $14.50, $18.00 and
$25.00 a barrel. The upper figure can only be considered a guess represent-
ing a conservative bias about future oil “real” price increases. This range
is intended to examine the effects of price on the economics of development
rather than to claim with any degree of certainty that these upper and lower”
limits are the limiting brackets.
3.5.4.4 Gas Prices
Well-head gas prices will be assumed to be the price allowed in mid-1979
by the Natural Gas Act of 1978, i.e., $2.60 MCF. Price increases subse-
quent to the 1979 price defined by the regulations are designed to move
with general inflation plus 3.5 percent to 1981. We believe production
costs will inflate faster than general inflation. Thus, assuming prices
and costs will move equally from 1979 to whenever the gas is produced,
TABLE 3-7
VALUE OF NORTH SLOPE CRUDE ON GULF COAST REPLACINGIRANIAN LIGHT, ARABIAN LIGHT, OR ISTHMUS
●
Iranian Light Arabianor isthmus Light
Crude laid-in to Gulf Coast $23.25 $20.00
Less quality differential for North Slope H M
Equals value of North Slope crude on Gulf Coast 22.75 19050
Less trans from Valdez to Gulf Coast m m
Equal: value of North Slope crude at Valdez $19.75’ $16.50 9
Source: PIW (various issues); Platt’s Oilgram~ (various issues).
●
~1) Our economic analysis was conducted prior to the December, 1979, OPECmeeting in Venezuala which failed to reach agreement on oil prices and priorto the December pre-OPEC meeting price increases led by Saudi Arabia. Our=Norton Basin oil and gas marketing study (Appendix F), which was conductedafter completion of our economic analysis, provides more current information(January 1980) on OPEC oil pricing.
ao
975
..-. . . . . . . . . . . . .
Ithe 1979 price together with 1979 costs will allow a valid economic approxi-
mation of the requirements to produce gas in the Norton basin. Gs prices and
the market ability of Norton Basin
I. A major ongoing research effort(1) It is not at allAlaskan gas.
ported at a cost of $3.00.to $5.00
Canadian, Mexican, and U.S. natural
gas are discussed in detail in Appendix
is addressing this thorny question about
clear that gas in Alaska can be trans-
MCF to lower 48 markets and compete with
gas in the late 1980’s.
In view of the unresolved economic questions, no solid basis exists to
net back to the Alaskan well-head a price based on market conditions.
Thus we will adopt the regulated
Monte Carlo calculation. Upper
MCF.
gas price as the mid-range value for the
and lower values will be $2.30 and $3.25
3.5.4.5 Effective Income Tax Rate and Royalty Rate
IFederal taxes on corporate income now stand at 46 percent of taxab”
Dames & Moore assumes revenues from Norton Sound development would
mental and taxable at 46 percent after the
cated below. Tracts are in federal OCS.
e income.
be incre-
usual industry deductions indi-
No state or local tax applies.
Royalty is assumed to be 16-2/3
consultation with BLM economists
judgment was adopted that future
outcome of this analysis.
percent of the value of production. In
(re: the Gulf of Alaska studies), their
royalty schemes would change little the
3.5.4.6 Tax Credits Depreciation and Depletion
Investment tax credits of 10 percent apply to tangible investments. Depre-
ciation is calculated by the units-of-production method. No depletion is
allowed over the production life of the field.
(1) Tussing, Arlon and Connie Barlow. Three papers on the gas problems,published November 1978 through April 1979, for Legislative Affairs Agency.
3.5.4.7 Fraction of Investment as Intangible Costs
Dames & Moore assumes that expenses will be written off as intangible
drilling costs to the maximum extent permissible by law. Fifty percent of
investment totals are considered to be intangible expenses. Expenses in==
curred before production are carried forward until production begins and then
expensed against revenue. The 50 percent fraction is consistent with an
industry rule-of-thumb.
3.5.4.8 Investment Schedules
Continuous discounting of cash flow is assumed to begin when the first
development investment is made. This assumes that time lags and costs for
permits, etc., from the time of field discovery to initial development
investment is expensed against corporate overhead. This is a critical
assumption which has the effect of removing 12 to 24 months of discounting
from the ultimate cash flow and making minimum field size calculated smaller
than if the lags were included.
Typical investment schedules for the various production technologies identi-
fied in Section 3.4 are a function of the selected technological assumptions.
These assumptions are discussed in Appendix 8.
Both tangible and intangible investment costs will be entered into the model
as lower, mid-range, and upper limits. The lower limit is derived from
calculations and is estimated to be 75 percent of mid-range. The upper
limit, also derived from calculations, is estimated to be 150 percent of the
mid-range. The model yields a base case solution on the mid-range investment
level along with the sensitivity tests at the upper and lower limits. In
some cases, Monte Carlo analysis will also be used over these ranges of
values.
●
77
3.5.4.9 Operating Costs
Annua’ operating costs are entered as fo” lows:
One Platform Field
Two Platform Field
Three Platform Field
$Mi”41ions 1979Mid-Range Value
40
80
115
A fixed annual operating cost based cm the number of platforms required
was determined by the study team to be a reasonable model of these costs ‘
given the uncertainties of the data base. In reality, operating costs
will fluctuate during the life of the field. There are several other
approaches to estimating or modeling operating costs such as costing by
throughput or number of wells; for a discussion of these and problems
related to modeling operating costs the reader is referred to a report
by Gruy Federal, Inc., 1977.
78
4.0 SCENARIO DEVELOPMENT
4,1 Identification of Skeletal Scenarios and Selection of Detailed
S c e n a r i o s
The cases that were screened in the economic analysis were selected as e
reasonably representative of’:
(a) Probable production technologies
environments.
n shallow water ice-infested
(b) Field sizes likely to justify development within the resource
levels defined by the U.S. Geological Survey.
(c) Probable reservoir characteristics (well productivity, depth,
etc.).
(d) Anticipated ranges of waterdepths and distances to shore of
possible of? and gas discoveries in Norton Sound.
The economic analysis, as discussed ,in Section .3.5, defines those field
sizes, discovery locations, production systems, and reservoir conditions
that are economically viable under the assumptions uf the analysis.
Since there is still a considerable number of permutations of field size,
production technologies and discovery situations (water depth, distance to
shore, geographic location) which have been demonstrated to be economically
viable, it is necessary to limit the number of possible developmental options
at each level of resource discovery (high find, medium find, low find, no
commercial resources) through application of some basic assumptions and
determination of the key parameters governing potential impacts on the
Alaskan economy and environment.
A three phased approach in the
point in the study:
6 A number of skeletal
scenario development is
petroleum development
conducted at this
scenarios are de-=
fined with various combinations of discovery location (water
●
*o
e
79
depth, distance to shore, etc.), production systems, field
sizes and reservoir characteristics (depth, initial well
productivity) which have been shown to be economic.
c The staff of the Bureau of Land Management, Alaska OCS Office
selected from among the suggested skeletal scenarios one
scenario to be
e The equipment,
requirements,
find, medium
detailed for each resource level.
materials, facilities, manpower and siting
and scheduling of each selected scenario (high
find,
were detailed to show
Tables 4-1 thr”ough 4-11 prov
sidered for selection by 5LM.
It is important to point out
low find, no commercial resources found)
the magnitude of impacts.
de skeletal scenario options (cases) con-
that the location, production and reservoir
characteristics, field size, and infrastructure sharing arrangements
associated with each of the scenarios are essential combinations to
generate a rate of return sufficiently large to induce development. In
other words, we recognize that the conditional probability of all of the
characteristics that define the skeletal scenarios is somewhat low -
lower, without doubt, than the U.S.G.S. estimates of “economically
recoverable resources”. However, if any of the characteristics are much
changed from those described in the skeletal scenarios, the reserves
quickly become uneconomic and undevelopable.
Since there is insufficient geologic data to identify the location,
number, and reserve potential of prospects or structures, three geo-
g r a p h i c a l l y r e p r e s e n t a t i v e d i s c o v e r y l o c a t i o n s in t h e N o r t o n S o u n d a r e a
have been defined for scenario formulation:
o Inner Norton Sound (longitudes 162° W to 164° W).
o Central Norton Sound (longitudes 164° W to 166° W).
● Outer Norton Sound (west of longitude 166° W).
m-l
-rA8LE 4-1
HIGH FIND OIL H4XIMJM ONSHORE lt@ACT
,
!
ield,izeOilM
500
200
200
500
200
750
250
Locatior
InnerSound
InnerSound
InnerSound,
CentralSound
CentralIsland
OuterSound
OuterSound
ReservfMeter!
2,286
2,286
2,286
2,286
2,286
2,286
2,286
*
7,500
7,500
7,500
7,500
1,500
7,500
7,500
Product ton System
Gravel island sharedpipeline to shoreterminal
Gravel island withshareci pipeline toshore terminal
Gravel Islandshared pipeline toshore terminal
Steel platforms withshared pipeline toshore terminal
Steel platform withshared pipeline toshore terminal
Steel platforms withshared pipeline toshore terminal
Steel platfotm withshared pipeline toshore terminal
PI atformNo. /Type*
26
IG
lG
2 s
1s
3s
1s
Number ofProduction
Wells
80
40
40
80
40
120
40
Initial HellProduct ivity
(B/D)
2, 00D
2,000
2,000
2,000
2,000
2,000
2,000
Peak’Product ionOil (M8/0]
153.6
76.8
76.8
153.6
76.8
230.4
76.8
mMeter
18
18
18
18
21
30
30
W!L: eet
60
60
60
60
70
100
100
‘ipeline Co Shore 1ilometers
19
40
40
30
56
129
140
itance-minalm
12
25
25
19
35
80
87
Trunkipel ineiameterinches)Oil
20
20
20
16-18
16-18
20
20
Shorererminal.ocation
CapeDarby
CapeDarby
CapeDarby
CapeNome
CapeNome
CapeNome
CapeNome
G = Caisson retained gravkl-; slan~.
Fields in same bracket share trunk pipeline.
* S = Ice reinforced steel nlatform.
Note: This skeletal scenario option specifies reservoir conditions and technical characteristics that are the most econcmic for the water depth specified.
Source: Dames & Moore
9
-
FieldSizeOilw
[
500
200
1’200
(
750
250
1200
L500
Location
CentralSound
CentralSound
CentralSound
OuterSound
OuterSound
OuterSound
l--CentralSound
Reserv{— . .Meter:
2,286
2,286
2,286
2,286
2,286
2,286
2,286
+?w#
7,500
7,500
7,500
7,500
7,500
7,500
7,500
Production System
Steel platforms withshared pipeline toshore terminal
Steel platform withshared pipeline toshore terminal
Steel platform withshared pipeline toShore tenminal
Steel platforms withshared pipeline toshore terminal
Steel platform withshared pipeline toshore terminal
Steel platform withshared pipelinetishore terminal
Steel platforms withunshared pipeline toshore terminal
TA8LE 4-2
HIGH FIND OIL MINIMJMONSHORE INPACT
P1 at forms40./Type*
2 s
1 s
Is
3 s
1 s
1 s
2 s
Number ofProduct ion
Nells
80
40
40
120
40
40
80
nitial Well‘productivity
(We)
2 , 0 0 0
2,000
2,000
2,000
2,000
2,000
2,000
PeakProductionOil (MB/D)
153.6
76.8
16.8
230.4
76.8
76.8
153.6
laterIeter:
18
21
24
30
30
34
18
g
60
70
80
100
100
110
60
‘ipel ine Io Shore~
30
56
56
129
140
145
69
,tanceminallTill%-
19
35
35
80
87
90
43
Trunki pel i neiameterinches)Oil
20
20
20
20-24
20-24
20-24
16
ShoreTerminalLocattor
CapeNome
CapeNome
CapeNome
CapeNome
CapeName
CapeNome
CapeNome
* S = Ice reinforced steel platform.
Fields in same bracket share trunk pipeline.
Note: This skeletal scenario option specifies reservoir conditions and technical characteristics that are the most economic for the water depth specified.,
Source: Dames & Moore
TABLE 4-3
MEDIUM FIND OIL flAX It4UM ONSHORE IWACT
coL.)
FieldSizeOil
f4MRBL ~
[200
(200
[
500
250
[250
Location
InnerSound
InnerSound
CentralSound
CentralSound
OuterSound
ReservMet er
2,286
2,286
2,286
2,286
2,286
E_&&
7$500
7,500
?,500
7,500
7,500
Production System
Gravel isl and withshared pipeline toshore terminal
Grqvel isl and withshared pi pel ine toshore terminal
Steel pl at, forms witkzshared pipel ine toshore terminal
Steel platform withshared pipeline toshore teiminal
Steel pl.atfmn withshared pipeline toshore terminal
PT atformsNo ./Type*
lG
IG
2s
Is
1$
!umber of%-oduction
Hel 1s
40
40
80
40
4?
[iaitial WellProduct ivity
(BID I
2,000
2,000
2,000
2,000
2,000
PeakProduct ionlil (#fB/D)
76.B
76.8
153.6
76.8
?6.3
Jaterm
18
18
lB
21
xl
+
Pipeline Distancez th to Shore T‘eet Kilometers
60 19
60 40
60 30
70 5 6
.
1-
%
minalm
12
25
19
35
5ii
TrunkPipelineDiameter(i;~es)
16
16
20
20
20
ShoreTerminaLocatiol
CapeOarby
CapeDarby
CapeNome
CapeNome
CapeNome
* S = Ice reinforced steel platform.G = Caisson retained gravel island.
Fields in same bracket share trunk pipeline.
Note: This skeletal scenario option specifies reservoir conditions and technical characteristics that are the most economic for the water depth specified.
So,urce: Oames & Moore
a o ●
ieldi zeoilw
500
250
250
200
200
.ocation
CentralSound
CentralSound
OuterSound
CentralSound
OuterSound
leserv{Meter:
2,286
2,286
2,286
2,286
2,286
‘ Ogl
7,500
7,500
7,500
7,500
7,500
Production System
Steel platforms withshared pipeline toshore terminal
Steel platform withshared pipeline toshore tenminal
Steel platform withshared pipeline toshore terminal
Steel platform withshared pipeline toshore terminal
liteel platform withshared pipeline toshore terminal
TABLE 4-4
MEDIUM FIND OIL MINIMUMONSHORE INPACT
PI atformsNo. f Type*
2 s
Is
Is
1 s
1s
Number ofProduct ion
Wells
80
40
40
40
40
Initial WellProduct ivity
(8/D)
2,000
2,000
2,000
2,000
2,000
PeakProductionJil (M8/0]
153.6 ‘
76.8
76.8
76.8
76.8
Pipeline IWater Depth to Shore ;Meters Feet Kilometer:
18 60 30
21 70 56
30 100 93
24 80 56
34 110 96
;tanceminalm
19
35
58
35
60
Trunkipel infiameteiinches]Oil
24-30
24-30
24-30
24-30
24-30
-
ShoreTerminalLocat i or
CapeNome
CapeNome
CapeNome
CapeNome
CapeNome
* s= Ice reinforced steel platform.
Fields in same bracket share trunk pipeline.
Note: This skeletal scenario option specifies reservoir conditions and technical characteristics that are the most economic for the water depth specified.
Source: Oanes & Moore
TABLE 4-5
LOU FIND OIL SCENARIO t44X1Ml)MONSt10RE IMPACT
CentralSound
CentralSound
2,286
2,286
7,500
7,500
Steel platform withshared pipeline toshore terminal
Steel p)atfonn withshared pipeline toshore terminal
W atfomns?40. /Type*
Is
Is
Number of Initial WellProd~~ion Prod;;; iv i ty
40 2,000
40 2,000
I I TrunkPipeline
Peak PipelineProduction Mater Depth to Shore(Jjl [MO/D) Meters Feet Kilometer
76.8, 21 7(I 49
76.8 ’21 70 72 130 16
45 16
ShoreTerminalLocation
CapeNome
CapeNome
* S = Ice reinforced steel p~atfo~.Fields in same bracket share trunk pipeline.
Note: This skeletal scenario option speciffes reservoir conditions and technical characteristics that are the most economic for the water depth specified.
Source: Dames & Moore
●●
☛ 6 9 ?
xin
+
FieldSizeoil
MMBBL Location
200 CentralSound
180 CentralSound
1
ReserviMeter:
2,286
2,286
LpeJ!
7,500
7,500
TABLE 4-6
LOW FIND OIL SCENARIO MIN1tlJM ONSHORE IMPACT
PI atfornwProduction System No. /TypeJ
Gravel island with IGoffshore processing,storage and Ioadfng
Gravel island with IGoffshore processing,storage and loading
Number ofProduct ion
Wells
40
40
Inittal WellProduct ivity
(B/o)
2,000
2,000
PeakProduct ion~
76.8
76.8
HaterE
15
12
~Pipeline Distance Diameterto” Shore TKi 1 ometers
N/A
NIA Trminal (inches)Hi es Oil
N/A N/A
N/A N/A 3ShoreTerminalLocation
H/A
N/A
* G = Caisson retained gravel island.
Note: This skeletal scenario option specifies reservoir conditions and technical characteristics that are the most economic for the water depth specifie
Source: Dames k Moore
TABLE 4-7
HIGH FIND NON-ASSOCIATED GAS SCENARIO
Field Trunk
Size P i p e l i n eNumber of
GasInitial !dell Peak Pipeline Distance DiameterReservoir Depth Pl at forms Production Product iv i ty Product ion Water Depth to Shore Terminal (inches)( BCF ) Location Meters Feet Production System No. /Type* Hells (MMCFD)
LNGGas [MNCFD)
[
Meters Feet Kilometers Miles Gas Plant1,000 Central 2,286 7,500 Steel platforms with is 16
Sound15 240 20 66 51 32 24-28 Cape
shared pipeline to
I
LNG plantNome
1,000 Central 2,286 7,500 Steel platform withSound
-1s 16 15 240 18 60 43 27shared pipeline to
24-28 Cape
LNG plantNome
1,200 Central 2,286 7,500 Steel platfoi-m withSound
Is 16 15 240 20 66 54 33 20-24 Capeunshared pipel~ne toLNG plant Nome
* s= Ice reinforced steel platform.
Fields in bracket share same trunk pipeline.
Note: This skeletal scenario option specifies reservoir conditions and technical characteristics that are the most economic for the water depth specified.
Source: Dames & Moore
e*
● ● * 9
TABLE 4-8
MEDIUM FIND NON-ASSOCIATED GAS SCENARIO
<
0303
TrunkField P.i pel ineSize Number of Initial Well PeakGas
Pipeline Distance DiameterReservoir Depth PI at forms Product ion Productivity Product ion Water Depth to Shore Terminal (inches) LNG
(BCF) Location Meters Feet Production System No. /Type* Wel 1s (MMcFD) Gas (MMcFD) Meters Feet Kilometers Miles Gas Plant
[1,300 Cent ral 2,286 7,500 Steel platfoim with 1s 16 15 240 20 66 64 40 20-24 Cape
Sound shared pipeline to
1
LNG plantNome
1,000 Central 2,286 7,500 Steel platform with 1s 16 15 240 18 60 47 29 20-24 CapeSound shared pipeline to Nome
LNG plant
* S = Ice reinforced steel platform.
Fields in bracket share same trunk pipeline.
Note: This skeletal scenario option specifies reservoir conditions and technical characteristics that are the most economic for the water depth specified.
‘Source: Dames & Moore
I
FieldSizeGa $
-@Z)
1,200
Location
Cent ralSound
TAME 4-9
LOW FIND NON-ASSOCIATED GAS SCENARIO
Reservoir Depth PI atfonnsMeters ~ Feet Production System No. /Type*
I
2’28’17’5001*H’&’ ‘1 “Number ofProduction
Wel 1s
16
PeakProductionGas (MMCFD~
240
TrunkPipeline
Pipeline Distance DiameterNater Depth to Shore Terminal ( incys) LNGMeters Feet Kilometers Mi.1 es P1 ant
16 54 34 21 16-18 CapeNome
‘s= Ice reinforced steel platform.
Note: This skelet,al scenario option specifies reservoir conditions and technical characteristics that are the most econcmic for the water depth specified.
Source: Dames & kloore
*
TABLE 4-10
HIGH INTEREST LEASE SALE
I YEAR AFTER LEASE SALE7 * INo. o+ Wells
INo. o: Wells No. o: Wells
I4 6 4
I TOTAL WELLS = 14 IAssumptions:
1. An average well completion rate of approximately 4 months.2. An average total well depth of3,048 to 3,692 meters (10,000to 13,000 feet).
,,
3. Year after lease sale = 1983.4. Rigs include jack ups and drill ships in summer and somegravel islands in shallow water.
Source: Dames & Moore
o
TABLE 4-11
LOW INTEREST LEASE SALE
I YEAR AFTER LEASE SALE”1 2 3
No. of !.Jells No. of Wells No. of Wells
2 4 2
TOTAL idELiS =8
Assu~ptions:
1. An average well completion rate of approximately 4 months.2. An average total well depth of3.048 to 3.692 meters (10.000. .to 13,000 fezt).3. Year after lease sale = 1983.4. Rigrave”
Jsis
nclude jack ups and driands in-sha
1 ships in summer and someLw water.
Source: Oames & Moore
●
●
●
91
rThe facility siting evaluation presented in Appendix D has identified
five technically feasible sites for the location of a crude oil terminal
and/or LNG plant:
● Cd pe
@ Cape
● Nome
a Lost
Darby (Inner Sound).
Nome (Central Sound).
(Central Sound).
River (Outer Sound/Bering Sea).
● Northeast Cape, St. Lawrence Island (Outer Sound/Bering
Sea.
Given the economics of pipelining and other factors, production from dis-
coveries made east of longitude 167° W would probably be taken to onshore) facilities located at one of the first three sites. Cape Nome appears to
be the most suitable of these three sites.
The skeletal scenarios are based on the “unrisked” resource estimates pre-
sented in U.S. Geological Survey
1979, p. 36).
Oil (mi
Gas (bi
These are:
1 ons of barrels)
1 ons of cubic feet)
Open-File Report 79-720
Minimum Mean
360 1,400
1,200 2,300
(Fisher et al.,
Maximum
2,600
3,200
For descriptive purposes, the scenarios corresponding to minimum, mean,and maximum resource estimates are termed “low find”, “medium find”,
and “high find” respectively.
The skeletal scenario options are essentially based upon differences in
discovery locations that would affect the amount of onshore construction
) and related impacts, in particular, the number and location of onshore
terminals.
Some of the important conclusions of the economic analysis (see Appen-
dix A) that have affected the specifications of the skeletal scenarios
are:
* Shallow reservoirs (762 meters or
most assumptions of the analysis)
2,500 feet) would (uncle~
be uneconomic to develop.
o Field development economics are relatively insensitive to
water depth in Norton Sound.
* Reservoirs only capable of sustaining 1,000 b/d initial
production rates per well would (undermost assumptions of
the ana?ysis) be uneconomic to develop.
e. Fields that would have to support the total investment of a
pipeline to shore (i.e. unshared) greater than 48 kilometers
(30 miles) long would not earn a 15 percent hurdle rate;
offshore loading may be a development strategy in these cases.
e Assuming a medium == deep oil reservoir (2286 meters) per-
mitting 2000 b/d wells and a pipeline distance of 48 kilometers
(30 miles) or less to h shore terminal, the minimum economic
field size (assuming a 15 percent hurdle rate) in ~o~~on Sound
generally ranges between 200 and 250 million barrels.
●
* In shallow water (18 meters or less) gravel islands may be ●
economically competitive with steel platforms assuming adjacent
borrow materials and assuming that they are environmentally
acceptable.
●In all cases, the oil scenarios assume a medium to deep reservoir (2,286
meters or 7,500 feet), 2,000 b/d weJls, and 60,000 bbl/acre recovery.
Although 5,000 b/d wells were evaluated
more economic than 2,000 b/d or 1,000
selected for the scenario since 1,000
2 , 0 0 0 b / d i n i t i a l well p r o d u c t i v i t y i s
5 , 0 0 0 bide
in the economic analysis and are
b/d wells, 2,000 b/d wells were ●b/d wells proved uneconomic and 9geologically more realistic than
●
93
For those oil fields with relatively short, shared pipelines (<48 kil-
ometers or 30 miles), shallower reservoirs (1,525 meters or 5,000 feet)
are generally economic although the number of platforms to drain a given
field size would be double
acre. This substitution or
fications. Doing such has
of employment generation.
A further variation
illustrated in the
could be discovered
assuming the same recoverable reserves per
variation is possible in the scenario speci-
important socioeconomic implications in terms
can also be postulated in the skeletal scenarios as
low find oil options. Some of the Norton reserves
in small, isolated fields, distant from suitable shore
terminal sites; there are two areas where long offshore pipelines would be
required -- the shallow waters west of the Yukon Delta and the western
portion of the area of call midway between Cape York (Seward Peninsula) and
St. Lawrence Island. In these locations, the development strategy of off-
shore loading may be the development option for isolated fields.
also be postulated that certain portion of the high or medium
resources would be offshore loaded obviating the need for lengthy
pipelines and onshore terminals.
It could
find oil
offshore
The skeletal scenario tables are introduced in the following paragraphs.
Possible variations in scenario specifications are noted where applicable.
4.1.1 Oil Scenarios
High Find Maximum Onshore Impact (Table 4-IL
This skeletal scenario postulates that discoveries are made in three widely
separated locations necessitating two crude oil terminals, one at Cape I)arby
a n d t h e o t h e r at.Cape Nome. Three major trunk pipelines would be constructed.
Gravel islands are assumed to be the development strategy for the fields near
Cape Darby. Oepending upon the order of discovery, production character-
istics, hydrocarbon characteristics, unitization agreements, etc., a single
crude oil terminal in the central and inner portion of Norton Sound is,
however, more likely given possible pipeline distances and hydrographic
conditions (there would be tanker size restrictions at Cape Darby).
w
●
.
In keeping with the concept of “maximum impact”, this scenario could be o
m o d i f i e d so that the tota l resource is discovered in a larger n u m b e r o f *
fields that are more widely dispersed.
High Find Minimum Onshore Impact (Table 4-2)@
This skeletal scenario assumes that only one crude oil terminal (at Cape
Nome) is
Nome and
Rodney.
together.
constructed to serve two “clusters” of fields, one located south of
the other approximately 64 kilometers (40 miles) southwest of Cape
This scenario could be modified by assuming fewer fields closer 9
Medium Find Maximum Onshore Impact (Table 4-3~
e
As postulated in the high find scenario, maximum development would occur
assuming widely scattered fields requiring two terminals. This option
assumes two crude terminals - one at Cape Darby and the other at Cape
Nome. *
Medium Find Minimum Onshore Impact (Table 4-4)
This option, as with the high find minimum impact case, postulates construe-= ●
tion of only one terminal at Cape Nome to serve two clusters of fields, one
south of Nome - the other southwest of Cape Rodney, sharing a single trunk
pipeline.
●Low Find Maximum Onshore Impact (Table 4-5)
This scenario postulates two fields south of Nome sharing a single pipeline
to a crude terminal at Cape Nome. ●
Low Find Minimum Onshore Impact (Table 4-6)
For some small fields isolated from other discoveries, and distant from ●suitable terminal sites, offshore loading of crude may be the more economic ooption obviating the need ~~r a long offshore pipeline and
m95
shore terminal. This skeletal scenario postulates discovery of two smal,l
fields about. 120 kilometers (75 miles) south of Nome; caissonretained gravel
islands are
the storage
4.1.2
used as production platforms with one of the islands providing
and loading facilities.
Non-Associated Gas Scenarios (Tables 4-7, 4:8, and 4-9~
To be economically developable the postulated gas resources of Norton
Sound would have to be found in a few large fields, generally one tcf
reserves or greater. Furthermore, it is unlikely, given the gas resources
estimated, that more than one LNG plant would be constructed. This restricts
the developmental options that can be formulated. No skeletal scenario
options were, therefore, proposed for gas. However, some variation in impact
potential” is possible by assuming different discovery locations (the scenar-
ios presented in Tables 4-7, 4-8, and 4-9 assume discoveries about 32 to 64
kilometers [20 to 40 miles] south of Nome). To be economic the fields should
share pipelines if greater than 48 kilometers (30 miles) from shore.
4.1.3 Exploration Only
Two exploration scenario options are provided reflecting high industry
interest (Table 4-10) and low industry interest (Table 4-11) in Sale 57.
4.1.4 Scenarios Selected for Detailing
The following ske?etal scenarios were selected by BLM staff for detailing:
Table 4-1 ,High Find Oil -- Maximum Onshore Impact -=- at the request
of BLM staff, this scenario was modified by assuming that
the Cape Darby fields would also produce to a Cape Nome
crude terminal which is also an economic option under the
assumptions of the analysis. In terms of impact assessment
this modification restricts onshore development to a
b
single crude oil terminal although increasing onshore pipeline
construction through the requirement to build a 100-kilometer
(62-mile) oil line between Cape Darby and Cape Nome.
Table 4-3 Medium Find Oil - Maximum Onshore Impact - as with the
high find oil scenario, this scenario was selected with
the same modification, i.e., Cape Darby fields producing
through d~ onshore pipeline to a Cape Nome crude oil term~na?.
Table 4-5 Low Find Oil - Maximum Onshore ~mpact - (selected with-
out modification).
Non-associated Gas
Tables 4-7, Non-associated gas scenarios, for which alternate develop-4-88 ~-9 ment cases were not provided, were approved by BLM staff
without modification.
Exploration Only
Table 4==11 Low interest lease sale.
4.2 Detailing of Scenarios
4.2.1 Introduction
The basic characteristics of the selected scenarios have already been
defined in the skeletal scenarios (platform, pipeline and shore facility
requirements, and general location). Detailing of the scenarios involvesthe following basic steps:.
@ Location of fields..
e Identification of an exploration and field discovery schedule.
●
8
9
97●
o Specification of major facilities requirements and their siting.
e f-ormulation of field development (construction) and opcrdtion
schedules.
● ✎ Translation of field development and operation schedules into
employment estimates.
4.2.2 The Location of Fields
The first step in scenario detailing is the location of fields identi-
fied in the selection of the skeletal scenario (the general location of
the field has already been defined by distance to terminal site, water
depth, etc.). If possible, the field should be located on a known geologic
structure of sufficient (apparent) size to accommodate the reserves within
the range of recoverable reserves per acre assumed in the analysis. Further,
the size and number of fields specified should be made to be consistent with
estimated resources and the results of field size distribution analysis.
In this study, the geologic data is insufficient to locate structures,
estimate percent fill-up, and conduct a field size distribution analysis.
Therefore, the location of fields is arbitrary but designed to provide
three geographically representative discovery locations for impact assessment.
As noted above, these are:
o Inner Norton Sound (longitudes 162° W to 164° M).
o Central Norton Sound (longitudes 164° h’ to 166° W).
o Outer Norton Sound (west of 1 ongitude 166° W).
4.2.3 Exploration and Field Discovery Schedules
The exploration and field discovery schedules forming the basis of the
CIQ
scenario descriptions were formulated to be consistent with the following
considerations:
An exploratory effort consistent with the postulated resources
at an assumed rate of discovery which has been sustained historic-
ally in some other offshore areas (a high discovery ratio is
assumed for the high find scenario and more modest success ratio
for the medium and low find scenarios).
An exploration pattern that builds up to a peak and theri declines
as prospects become fewer and more difficult to find and as petrol-
eum company resources shift from exploration to field development
investment.
The larger fields are in general discovered and developed first.
Most of the discoveries are made within five years of the lease
sale (i.e. the initial tenure of the leases).,
Although availability of exploration rigs at the time of the
●
9
lease sale cannot be predicted, the number of drill rigs and‘e
exploration well scheduling has been tailored to discover most,
if not all, of the postulated resources within the five year
tenure of the leases.
As explained in Appendix B, once a discovery has been made two or three
delineation wells are assumed to be drilled and the decision to develop
is assumed to be made 18 to 24 months after discovery. Significant invest=ment in field development is assumed to commence the year following the
decision to develop. Implicit in this schedule is some delay related
environmental regulation. The first year of significant investment in
field development is the year in which contracts are placed for platforms,
process equipment,. etc.; this is year 1 of the investment schedule as
used in the economic analysis (see Appendix B).
●
99.- . . ____ . . .
4.2.4 ~
The major shore facility requirements of Norton Sound petroleum develop-
ment to a large degree will depend upon the production options discussed
In Section 3.4 and the assumed location and distribution of fields. ln
this study, a facilities siting analysis (see Appendix D) is conducted
concurrently with the petroleum technology review (Appendix C) to assess
the field development and transportation options for economic analysis
and scenario specification. For each representative discovery location,
technically and economically feasible crude oil terminal and LNG plant
sites are identified.
4.2.5 Field Development and Operation Scheduling
Once discovery and decision-to-develop dates have been established, field
development schedules are defined for each scenario based on the assump-
tions explained in Appendix F3; these are consistent with schedules in) other offshore areas modified for the environmental constraints peculiar
to Norton Sound. Schedules for each scenario are shown on a series of
tables showing the timing of platform installation and commissioning,
development well drilling, major facilities construction, pipelaying,
etc. For each field, a production schedule is identified based on the
production timing and production decline rates defined in Appendix A.
These provide information on production start-up and field life necessary
to determine the timing of facilities construction (marine terminals,
pipelines, etc.) and the operational life of the field. Each of the construc-
tion and production schedule tables presented in Chapters 6.0, 7.0, and 8.0
for the high, medium,
tables are interrelated
affects the others.
and low find scenarios is compiled in sequence; the
such that a change in one assumption or specification
4.2.6 Translation of Field Development and Operation Schedules
Into Employment Estimates
) The field development and operation tables developed for scenario detailing,
supplemented by information on the size of facilities (e.g. marine terminal
Inn
capacity in barrels per day) or location of construction work (e.g. water ●depth of pipelaying), form the basis for estimating scenario employment.
The components of the construction and operation schedule are broken down
into a number of employment tasks (development drilling, platform install-
ation and commissioning, terminal and pipeline operations, etc.) of specified
durations. Using a computer program specifically developed for this series
of scenario studies, the scenario employment calculations ‘are made. The
methodology and assumptions of this OCS manpower model are explained in
Appendix E. The reader is also referred to a worked example of these compu-=
tations in a companion report of the Alaska OCS Socioeconomic Studies Program
(Northern Gulf of Alaska Petroelum Development Scenarios, Appendix D, Dames &
Moore, 1979a),
●
●
●o●
101
. .
102
5.0 EXPLORATION ONLY SCENARIO
5.1 General Desc~fption
l%e exploration only scenario assumes that no commercial oil and/or gas
resources are discovered. Industry interest is low and principally centered
in central Norton Sound. A low level of exploration with only eight wells
drilled over a period of three years characterizes the exploration program
(Table 5-1).
Exploration is conducted principally in the four month summer open-water
season using jack ups augmented by drillships in the deeper water of the
outer sound (the waters of most of Norton Sound are too shallow to use
semi-submersible rigs). Two of the wells located in the shallow water (less ●than 18 meters [60 feet]) are drilled with conventional rigs from summer-con-
structed gravel islands.
5.2 Tracts and Location *
No tracts are specified in this scenario. The total of wells drilled
(eight) indicates that eight of the leased tracts are drilled (the assumption
has been made that no more than one well is drilled per tract). Several of
the larger structures are explored with
number of prospects examined is somewhat
drilled.
5.3 Exploration Schedule
The exploration schedule, presented in
more than one. well, thus the total
less than the total number of wells
Table 5-1, shows that exploration
commences in the first year after the lease sale, peaks in the second
year, and terminates in the third year after discouraging results.
5.4 Facility Requirements and Locations
Exploration in Norton Sound will be conducted by a combination of jack up
rigs, drillships, and a few gravel islands in shallower water (if environ-
●
103
TABLE 5-1
EXPLORATION ONLY SCENARIO - LOW INTEREST LEASE SALE
YEAR AFTER LEASE SALE1 2 3
Rigs Wells I Rigs Wel 1s Rigs Wells . . . .
2 2 3C 4 lC 2
IG IG
1
I TOTAL WELLS = 8I
c = Conventional rigs (jack ups or drillships)G = Gravel island
Assumptions:
1. An averaqe well comr)letion rate of a~~rcximately 4 months.2* An avera~e total w?il depth of 3,048”(10 ,000 to 13,000 feet).3. Year after lease sale = 1983.4. Rigs include jack ups and dri-summer-constructed gravel islands
Source: Dames & Moore
to 3,692 miters
ships in summer and somen sha” low water.
mentally acceptable and if adjacent borrow materials are available).
Exploration support will be a problem in Norton Sound due
isolation, the lack of local infrastructure, including ports,
port sites. Significant investments would be required to
facilities even for supply boats. Because of these problems,
to geographic
and potential
provide port
this scenario
postulates that Nome would be a forward support base for air-shipped light
supplies and personnel shipment. Heavy supplies (mud, cement casing, etc.)
are assumed to be stored on location in freighters or barges moored in Norton
Sound with transshipment to rigs provided by supply boats. In addition, a
rear support base providing storage and shipment for heavy supplies is
assumed to be located in the Aleutian Islands.
5.5 Manpower Requirements
The manpower requirements associated with the exploration program are pre-
‘ sented in Tables 5-2 through 5-5.
5.6 Environmental Considerations
With the low drilling activities anticipated in this scenario, vessel
and aircraft traffic will be the principal source of environmental impact.
Two areas are particularly susceptible to traffic disturbance. On the
western margin of Norton Sound exploratory activities are likely to disturb
aggregations of seals and walrus, especially in early spring (April) when
reproductive activity occurs and navigable routes will be Iimiteci. Precau-
tions to avoid areas frequented by pregnant or nursing females should be
taken. Sledge Island, a federal marine resource withdrawal area and site of
established seabird colonies, should also be avoided in routing of vessels
and aircraft. The inner islands of Norton Sound
Islands) are also ’sensitive seabird areas.
Construction of shallow-water gravel islands may
resources in the Nome area. Hydrographic surveys
precede island construction to determine the extent
increases.
(Besboro, Stuart, and Egg
potentially harm fishery
of the well site should
and direction of turbidity●o
105
-.
—
1 6-+,>. ,?. II . !). ?ih+. 511. 11. 766. 105. R14./ b-in. I1}L. 41.1,. :1(1 . 41!7. 112. 0. Ihlz.3
246.4%”. 5? .
2(15R.:,11,1 * 3 0 . /(}@* 5 6 . 0. 11060 1.M!. 1244.
.
*
Q.G.O
.0.V(wulFlmulm.a.a
**..nI’-l-l%. 3.7
. . .Qn%l
!m l-11-n-$%%
.*.= ==
eo
m 0“ 0“ o“ 0“ ; 0-.
. .0 0
> . .0 0
e.0 053
.
c.
.
. .*
r]2. .== . .-+=..>.Q.3. .-. ->
a .7
.4.1. .r. -
L
,, ,,.1-..
1-.-. .
,..: .
f!!
108
TABLE 5-4 (Attachment)LIST OF TASKS BY ACTIVITY
Activity1
2
3
4
5
6
7
8
9
10
Service Bases
Task 1 -Task 2 -Task 5 -Task 6 -Task 7 -Task 8 -Task 11 -Task 12-Task 13 -Task 20-Task 23-Task 24-Task 27 -Task 28-Task 31 -Task 33-Task 37 -Task 301 -
ONSHORE
(Onshore Employment - which would include allonshore arhainistration, service base operations,rig and platform serviceExploration kfell DrillingGeophysical ExplorationSupply/Anchor Boats for RigsOevelopnent DrillingSteel Jacket Installations and CommissioningConcrete Installations and CommissioningSingle-Leg Mooring SystemPipeline-Offshore, Gathering, Oil and GasPipeline-Offshore, Trunk, Oil and GasGravel Island ConstructionSupply/Anchor Boats for PlatformSupply/Anchor Botits for Lay BargeLongshoring for Platfon *Longshoring for Lay BargePlatform OperationMaintenance and Repairs for Platform and Supply BoatsLongshoring for Platform (Production)Gravel Island Construction
Helicopter ServiceTask 4 - Helicopter for RiasTask 21 - Helicopter Suppor~ for PlatformTask 22 - Helicopter Support for Lay BargeTask 34- Helicopter for Platform
ConstructionService Base
Task 3 - Shore Base ConstructionTask 10- Shore Base Construction
Pipe CoatingTask 15 - Pipe Coating
Onshore PipelinesTask 14 - Pipeline, .Onshore, Trunk, Oil and Gas
TerminalTask 16 -Task 18 -
LNG PlantTask 17 -
Marine Terminal (assumed to be oil terminal)Crude Oil Pump Station Onshore
LNG Plant
Concrete Platform ConstructionTask 19 - Concrete Platform Site PreparationTask 20 - Concrete Platform Construction
Oil Terminal OperationsTask 36 - Terminal and Pipeline Operations
LNG Plant Operations.Task 38 - LUG Operations
Activity11
12
13
14
15
16
OFFSHORE
_2 - Geophysical and Geological Survey
RirJ_sTask 1 - Exploration Well
P1 at formsTask 6 - Development OrillingTask 31 - OperationsTask 32 - Workover and Well Stimulation
Platform InstallationTask 7 - Steel Jacket Installation and CommissioningTask 8 - Concrete Installation and CommissioningTask 11 - Single-Leg Mooring SystemTask 20 - Gravel Island constructionTask 301 - Gravel Island Construction
Offshore Pipeline Construction~ipeline O fshore, Gathering, Oil and Gas
Task 13 - Pipeline Offshore, Trunk, Oil and Gas
Supply~Anchor/Tug Boat5 - Supply/Anchor Boats for Rigs
Task 23 - SuDDIY/Anchor Boats for platformTask 24 ““ ‘“- Supply/Anchor Boats for Lay BargeTask 25 - Tugboats for Installation and TowoutTask 26 - Tugboats for Lay Barge SpreadTask 29 - Tugboats for SLMSTask 30 - Supply 8oat for SLt4STask 35 - Supply Boat forSLNS
-1
‘*c1
L
‘3t-
● ☛ ☛
Coae-o’nr-.ru -
. . .I-IWQ-l-u-
;::oam.-. SJ.
tL0
Y ,!J.L: Jl-uU. w,4
-1a
110
6.0 HIGH FIND SCENARIO
6.1 General Description
The high find scenario assumes significant commercial discoveries of oil ande
gas. The basic characteristics of the scenario are summarized in Tables 6-1
and 6-2. The total reserves discovered and developed are:
Oil (MM8BL)
2,600
These resources are
Non-Associated Gas (BCF)
.3,200
distributed in three “clusters” of fields located
respectively in inner Norton Sound south of Cape Darb~, central Norton
Sound south of Nome, and outer Norton Sound about 64 kilometers (40 miles)
southwest of Cape Rodney (Figures 6-1 and 6-2).
All oil and gas production is brought to shore by pipeline to a large
crude oil terminal and LNG plant located at Cape Nome. Production from
the central Norton Sound fields involves a direct offshore pipeline to
Cape Nome while production from the outer and inner Norton Sound fields
involves a significant onshore pipeline segment.
6.2 Tracts and Location
The discovery tracts
diagram numbers) are
relates to the optimal
analysis.
and their locations (designated by OCS protraction
given jn Table 6-3. The productive acreage cited
recoverable reserves per acre assumed for the scenario
*
*6.3 Exploration, Development, and Production Schedules
Exploration, development, and production schedules are shown on Tables6-4 through 6-14. The assumptions on which these schedules are based are
*given in Appendix B and El
o
●
111
— -
TABLE 6-l
HIGH FINO OIL SCENAR1O
FieldSizeOil
MMtlBL ;
[
500
1
200
200
(
500
L200
r
750
\250
Locat i or
InnerSound
InnerSound
InnerSound
CentralSound
CentralIsland
OuterSound
OuterSound
ReservfMeter:
2,286
2,286
2,286
2,286
2,286
2,286
2,286
‘ DeuthFeet
7,500
7,500
7,500
7,500
7,500
7,500
7,500
Production System
Gravel island sharedpipeline to shoreterminal
Gravel island withshared pipel ine toshore terminal
Gravel Islandshared pipel ine toshore terminal
Steel platforms withshared pi pel ine toshore terminal
Steel platform withshared pipel ine toshore terminal
Steel platforms withshared pipel ine toshore terminal
Steel platform withshared pipel ine toshore terminal
* S = Ice reinforced steel olatform.G = Caisson retained gravel island.
Fields in same bracket share trunk pipel inc.
Source: Dames S Moore
P1 atformsNo. /Type*
2G
lG
lG
2 s
1 s
3 s
Is
Number ofProduct iol
Hells
80
40
40
80
40
120
40
Initial WellProd#;; ivity
2,000
2,000
2,000
2,000
2,000
2,000
2,000
PeakProduct i orOil (MB/D)
153.6
76.8
76.8
153.6
76.8
230.4
76.8
mMeter
18
18
18
18
21
30
30
?Jl&‘eet
60
60
60
60
70
100
100
i~eline Oistanceo“ Shore 1i 1 ometer:
133
146
150
34
58
129
140
minalMiles
83
91
93
21
36
80
87
Trunk‘ipel ine~iameterinches)Oil
20
20
20
16-18
16-18
20
20
Shore[erminal.ocat ion
CapeNonE
CapeNome
CapeNome
CapeNome
CapeNome
CapeNome
CapeNome
TABLE 6-2
HIGH.FIND NCWASSOCIATEDGAS SCENARIO
[
1,000
Location
CentralSound
Cent ralSound
Cent ralSound
IeservcMet ers
2,286
2,286
2,286
+!&
7,500
7,500
?, 500
Production System
Steel platforms withshared pipeline toLNG plant
Steel platform withshared pipelfne toLNG plant
Steel platform withunshared pipeline toLNG plant
*s= Ice reinforced steel platform.
Fields in bracket share same trunk pipeline.
Sotirce: Dames & Moore
*e* @ ●
P] atfonns&&@l
Is
Is
Is
#
Number ofProduct ionUells
16
16
16
Initial HellProduct ivity
(MMCFD)
15
15
15
P
I
-FPeak
Product ion WaterGas tWFD Meters
240 2 0
240 18
240 20
I
ML‘eet
66
60
66
‘i~eline Distance;o” Shore 1[i 1 ometer:
51
43
51
minalm
32
2?
32
Trunk‘i pel ineliameter~inches)Gas
24-28
24-28
20-24
LNGPlant
CapeNome
CapeNome
CapeNome
O* ●
N
II
~igw-e 6-2 HIGH FINQ SGENAR10FIELD AND SHOREFACILITY LOCATIONS’INNER NORTON SOUND
Legend
o011 Field(Reserves In MM8BL)
fGas Field
~e_-~J (Reserves in BGF)
m ~r~de OJ1 ~efmina~
I al L~G Plant
A Service Baae
@p~rnp station orCompressor Station
~ OiI pipeline Corridor
●
B
9
●
a
‘9
m
1-
Location
Inner Sound
Inner Sound
Inner Sound
Central Sound
Central Sound
Outer Sound
Outer Sound
Central Sound
Central Sound
Central Sound
TABLE 6-3
HIGH FIND SCENARIO - FIELDS AND TRACTS
FielOil (mmbbl)
500
200
200
500
200
750
250
--
--
--
SizeGas (bcf)
--
-.
.-
--
--
--
-.
1,000
1,200
1,000
Acres t
8,333
3,333
3,333
8,333
3,333
12,500
4,167
4,000
3,333
4,000
Hectares
3,373
1,349
1,349
3,373
1,349
5,059
1,686
1,618
1,349
1,618
No. OfTracts 2
1.5
0.6
0.6
1.5
0.6
2.2
0.7
0.7
0.6
0.7
OCS Tract Numbersg
902, 903, 904, 946, 947
967, 968
1035, 1036
773, 774, 775, 817, 818
857, 858
756, 757, 800, 801, 802,8 4 5 , 8 1 6
667, 668, 712, 713
951, 952, 953, 995, 996
823, 866, 867
973, 974
~ Recoverable reserves in the scenario are assumed to be 60,000 barrels per acre for oil and 300 mmcf for non-associated gas.2 A tract is 2,304 hectares (5,693 acres).$ Tracts listed include all tracts that are involved in the surface expression of an oil or gas field. In somecases only portions (a corner, etc.) of a tract are involved. However, the entire tract is listed above. (SeeFigures 6-1 and 6-2 for exact tract location and portion involved in surface expression of fields.)
Source: Dames & Moore
mu 6-4
EXPLORATION SCtlEDULE FOR EXPLORATION AN~ DELINEATION WELLS - H~Gti F [ND SCENAR1O
Year After Lease SaleWe] 1 1 ! 2 3 4 5 1 ? I 8 I 9 I 10 Wel 1Type Rigs Wells Rigs Wells Rigs Wells Rigs Wells Rigs Mells Rigs Wells Rigs Wells Rigs Wells Rigs Wel 1s Rigs Wells Totals
Exp. 1 6 9 12 12’ 12 10 6 67
3 6 9 10 7 6 4
Del. 2 2 3 2 1 2 ~ 2 2 2 2 2 2 24
TOTAL 6 12 19 20 14 12 8 91
J In this high find scenario a success rate of one significant discovery for approximately every seven expiration wells is assumed. This is somewhathigher than the average of 10 percent success rate in u.S. offshore areas in the past 10 years and significantly higher than the average of the pastfive years (Tucker, 1978).Z The number of delineation wells assumed per discovery is two field sizes of less than 500 mmbbl oil or 2,000 bcf gas, and three for fields of500 mmbbl oil and 2,000 bcf gas and larger.3 An average completion time of four months per explo~at .~on/del ineat ion we]] iS assumed. The drilling season is assumed to be extended to a maximumw
w of eight months by ice breaker support. IrI addition, the 9imited use of summer-constructed gravel islands to extend drilling Into the winter is also--J postulated.
Source: Dames & Moore
● ● ●*
* * ●
—
Year AfterLease Sale
1
2
2
2
3
3
3
4
5
6
Type
oil
oil
Gas
Oi 1
Oil
Gas
Oil
Oil
Gas
Oil
TABLE 6-5
TIMING OF DISCOVERIES - HIGH FIND SCENARIO
Reserve SizeOil (mmbbl)’~ Gas (bcf)
500
750
.-
200
250
..”
500
200
--
20C
-.
--
1,000
--
--
1,000
--
--
1,200
--
Location
Central Sound
Outer Sound
Central Sound
Central Sound
Outer Sound
Central Sound
Inner Sound
Inner Sound
Central Sound
Inner Sound
WaterMeters
18
30
20
21
30
18
18
18
20
&&_
60
100
66
70
100
60
60
60
66
60
i Assumes field has IowGOR and associated gas is used to power-platform and reinfected.
Source: Dames & Moore
TAGLE 6-6
PLATFORM CONSTRUCTION ANO INSTALLATION SCHEDULE - liIGH FIND SCENARIO
Field Year After Lease SaleLocation 011 (mBBL) Gas (BCF] 1 2 3 4 9 10 11 12
Inner Sound 500 .- * D A~ AG
Inner Sound 200 . . * D AG
her Sound 200 -- * D AG
Central Sound 500 .“ * D As As
Central Sound 200 - - * D 4s
Outer Sound 750 -.. * D AS As &s
Outer Sound 250 _ - * D As
Central Sound -- 1,000 * D As
Central Sound -- 1,000 * c1 As
Central Sound -- 1 ,20U * D AS
* = Discovery; D = Decision to Develop; AS = Steel Platform; AG = Gravel Island
Notes:
1. Steel platform installation is assumed to begin in June in each case; gravel island construction starts the year after decisiontodevelop and takes two summer seasons.2. Platform “instal~at.ion” includes module lifting, hook-up, and commissioning.
Source: Dames & Moore
● ● 9 ● * 9@
*
—
TABLE 6-7
DEVELOPMENT HELL DRILLING SCHEDULE - HIGH FIND SCENARIO
No. 2 OfDrill Rigs
PerPlatform
2
2
2
2
2
2
2
2
2
2
2
1
1
1
Total.No. ofProduct iol
Hells
40
40
40
40
40
40
40
40
40
40
40
16
16
16
ltherfells’
8
8
8
8
8
8
8
8
8
8
8
-dMMJ3Bl_
500
200
200
500
200
750
250
--
--
--
:ld--ii-Z-Kl)_-.
--
--
--
-.
--
--
t ,000
1,000
[ ,200
itart ofIrjllingMont h
Apri 1
Apri 1
April
Apri 1
Apri 1
‘Apri 1
Apri 1
Apri 1
Apri 1
Apri 1
Apri 1
Apri 1
Apri 1
Apri 1
liti 2 -—
4
4
16f
w
4
2
z—
AftT—
bG
AG
16[
12
12
12
AS
s
6[
A!
z—
‘ L{11--—
12
16
161
161
161
12
As
12
6
61
%
~9—
16P
12
12
G
4
16
16
16
16F
12
16P
2
8
d:
z—
~Jo_
16
16P
16P
4
4
4
16
161
16
2
61
0. (——11.
4
16
16
12
4
16
4
8
G -—
PlaG
z{
1
1
2{
1
3’
1
1
1
1
~YE!
G
G
G
G
s
s
s
s
s
ss
s
s
s
iF-—
—
—
I
,:
i5-—
w
w
w
—
Location
Inner Sound
Inner Sound
Inner Sound
Central Sound
Central Sound
Outer Sound
Outer Sound
Central Sound
Central Sound
Central Sound
TOTALS 118
‘ S = Steei; G = Gravelz Platforms sized for 40 or more well slots are assumed to have two drill rigs operating during development drilling. Platforms sized for less than40 well slots are assumed to have one drill rig operating during development drilling.‘ Orilling progress is assumed to be 45 days perwell. -
‘ Gas or water injection wells etc. , well allowances assumed to one well for every five oil production wells.AS = p~atfonn arri~es on site -- assumed to be June; platform installation and commissioning assumed to take 10 months.AG = Gravel island construction starts June 1 the year after decision to develop and take two summer seasons.W = Work over commences -- assumed to be five years after beginning of production from platform.P = Production starts; assumed to occur when first 10 oil wells are completed or first four 9as wells.
Source: Dames & Moore
oTABLE 6-8
EXPLORATION AND PRODUCTION GRAVEL ISLANDS -HIGH FIND SCENARIO
Exploration Number ofYear After /5 ConstructionLease Sale (2; f:) (50 1) Production Total Spreads
1
2 1 1 1
3 1 1 1
4 1
\
1 2
5 1 “ 1 2
6 1
\
1 2 2
7 1 2 3 3
8
9 1 1 1
10
TOTALS 2 4 4 10 N/A
●
●
Note: Arrows show exploration islands expanded and mctdified for production.
TABLE 6-9
PIPELINE CONSTRUCTION SCHEOULE - HIGH FINO SCENARIO - KilOmeterS (MILES) CONSTRUCTED BY YEAR
Pipe] ine Diameter Year After Lease Sale(inches) Water Depth
011 Gas Meters Feet 1 2 3 4 5 6 7 8 9 10 11
18 0-18 0-60 34 (21)
12 18 60 13 (8)
12 0-18 0-60 16 (10)
16 18 0-60 30 (19)
12 18 60 24 (15)alL 18z 0-30 0-1oo 64 (40)C4- 120 30 100 11 (7)
24 0-30 0-60 48 (30)
16 18 60 10 (6)
24 0-30 0-60 48 (30)
Subtotal 78 (49) 98 (61) 44 (28) 61 (38) 16 (10)
18 100 (62) ~
16 3 (2)
18 64 (40)~
24 3 (2)2wEl 24 3 (2)
Subtotal 6 (4) 64 (40) 100 (62) 3 (2)
Tot al 84 (53) 162 (101) 144 (90) 64 (40) 16 (10)
Source: Oames & Moore
TABLE 6-10
MAJOR FACIL!T’IES CONSTRUCTION SCHEDULE - HIGH FIND SCENARIO
Facility ’/Location ~a
Cape Nome Oil Terminal 765 --
Cape Nome LNG PI ant -- 691,
Cape Nom Support Base(permanent] (large)
Year After Lease Sale4 5 6 “7 8 9 IQ 11 12
&
4 *
4 *
‘ Assume construction starts in spring of year indicated.+N(A Source: Oames & Moore
● 9 * 9 ● *e
● ●
—
L o c a t i o n
Inner Sound
Inner Sound
Inner Sound
Central Sound
Central Sound
Outer Sound
Outer Sound
Central Sound
Central Sound
Central Sound
+.J!!!!w
500
200
200
500
200750
250-.
--
. .
%%5--_JI!w-
--
.-
-.
--
-.
1,0001,000
1,200
TABLE 6-11
FIELD PRODUCTION SCHEDULE - HIGH FINO SCENARIO
153.6
76.8
76.8
153.6
76.8
230.4
16.8
. .
--
--
-.
-.
-.
--
230.4
2M.4230.4
Production “Start UP
9
10
12
7
8
8
9
7
8
10
n After Lease SProduct ionShut DOWII
28
29
31
26
27
34
22 ~
J
26
26
34
IePeak
Product ion
12-13
13
15
10-11
11
12-13
11-13
10-16
11-17
13-21
Years ofProductioni
20
20
20
20
20
127
14
20
20
25
‘ Years of production relates to the date of start up from first installed platform (multi-platform fields); production shut downoccurs at same time for all platforms.
Source: Dames & Moore
TABLE 6-12
H IGii FIND SCENARIO PRODUCTION BY YEAR FOR INDIVIDUAL FIELDS ANO TOTAL - OIL
~Calendar Year After Inner Sound Central Sound
Year lease SaleOuter Sound
~50 200 ~200 ~250 Totals
1983 11984 21985 31986 419B7 51988 61989 7 7.008 7.0081990 8 24.528 7.008 7.008 38.5441991 9 7.008 45.552 14.016 24.528 7.008 98.0B81992 10 24.528 7.008 56.064 21.024 52.560 17.5201993
178.70411 45.552 14.016 56.064 28.032 73.584 2B .032 245.280
1994 12 56.064 21.024 7.008 54.005 27.050 84.096 28.032 277.2791995 13 56.064 28.032 14.016 46.354 22.401 84.096 28.0321996 14 54.005 2?.050
278.99521.024 38.598 17.432 76.708 W .982
1997262.799
15 46.354 22.401 28.032 32.168 13.897 62.453 24.906 230.2111998 16 38.598 17.432 27.050 26.840 11.000 51.293 20.6471999
192.86017 32.168 13.897 22.401 22.420 8.886 40.869 17.116 157.757
2000 18 26.840 11.000 17.432 18.757 6.835 33.885 14.187 128.9362001 19 22.420 8.886 13.897 15.221 5.250 28.094 11.763 105.5312002 20 18.757 6.835 11.000 12.703 4.154 23.293 9.751 86.4932003 21 15.221 5.250 8.886 10.616 3.286 19.312 8.084 70.6552004 22 12.703 4.154 6.835 8.886 2.600 16.012 6.701 57.8912005 23 10.616 3.286 5.260 7.452 2.057 13.274 41.9352006 24 8.886 2.600 4.154 6.263 1.628 11.00? 34.53B2007 25 7.452 2.057 3.286 5.328 1.288 9.126 28.5372008 26 6.263 1.628 2.600 4.417 1.019 7.566 23.4932009 27 5.328 1.288 2.057 0.837 7.088 16.5982010 28 4.417 1.019 1.62B 5.876 12.9402011 29 0.837 1.288 4.872 6.9972012 30 1.019 4.040 5.0592013 31 0.837 3.349 “ 4.L862014 32 . 2.776 2.7762015 33 2.302 2.3022016 34 “ I .909 1.909
Peak 0{ 1 Product ion = 764,400 b/d.
Source: Oames h Moore
●
9
●
●
e
●125
. ..—. ______ .- —... . .
TABLE 6-13
HIGH FIND SCENAR [0 PRODUCTION BY YEAR FOR INDIVIDUAL FIELDS AND TOTAL - NON-ASSOCIATED GAS
PRODUCTION IN BCF YEAR BY FIELD SIZE (BCF)Calendar Year After
YearCentral Sound
Lease Sale 1000 000 1200 Totals
1983 11984 21985 31986 41987 5
1988 6
1989 7 21.024 21.0241990 8 42.048 21.024 63.0721991 9 63.072 42.048 105.1201992 10 84.096 63.072 21.024 168.1921993 11 84,096 84.096 42.048 210.240
1994 12 84.096 84.096 63.072 231.264
1995 13 84.096 84.096 84.096 252.288
1996 14 84.096 84.096 84.096 252.288
1997 15 84.096 84.096 84.096 252.288
1998 16 84.096 84.096 84.096 252.288
1999 1 7 7 2 . 4 2 3 84.096 84.096 240.615
2000 18 54.122 72.423 84.096 210.641
2001 19 40.521 54.122 84.096 178.739
2002 20 30.310 40.521 84.096 154.927
2003 21 22.672 30.310 84.096 137.078
2004 22 16.958 22.672 69.600 109.23
2005 23 12.685 16.958 54.680 84.323
2006 24 9.788 12.685 42.933 65.106
2007 25 7.097 9.488 33.710 50.295
2008 26 5.309 7.097 26.468 38.874
2009 27 5.309 20.782 26.091
2010 28 16.317 16.317
2011 29 12.812 12s812
2012 30 10.059 10.0592013 31 7.888 7.8882014 32 6.193 6.193
2015 33 4.862 4.862
2016 3 4 3.817 3.8172017 35
Peak Gas Production ❑ 691,200 mmcfd.
1Source: Oames & Moore
126
TABLE 6-14
MAJOR SHORE FACILITIES START UP AND SHUT DOWN DATES -HIGH FIND SCENARIO
Year Aftey Lease SaleFacility ~Start U Date
Cape Nome Oil Terminal 7 34
Cape Nome LNG Plant 7 34
~ For the purposes of manpower estimatJanuary 1.2 For the purposes of manpower estimat-
Source: Dames & Moore
on start up is assumed to be
on shut down is to be December 31.
●
●
●127
Exploration commences in the first year after the lease sale (1983), peaks in
year4 with 20 wells drilled, and terminates in the seventh year with a total
of 90 wells drilled (Table 6-4). Ten commercial discoveries are made (seven
oil, three non-associated gas) over a six-year period (Table 6-5). The
exploration program involves jack-up rigs and drillships (in the outer sound)
and limited use of summer-constructed gravel islands in shallow water (15
meters 150 feet] or less) where suitable borrow ma~erfals are either adjacent
to the well site or wf~hlfi economie-haul distance. Economics dictate extert-
sion of the drilling season from the four to six month open-water season to a
maximum of eight months; this is accomplished by the use of ice-breaker
support.
Field construction commences in year 4 after the decision to develop the
first discovery (a 500mmbbl oil field in central Norton Sound) and the first
platform is instal led in the summer of year 5 (Table 6-6). Development
drilling commences the following year and the first oil production is brought
to shore in year 7 (1989). The last platforms (a gravel island in inner
Norton Sound and a steel gas platform in central Norton Sound) are installed
in year 9.
Oil production from Norton Sound commences in year 7 (1989) after the
lease sale, peaks at 764,000 b/d in year 13 (1995), and ceases in year 34(2016) (Tables 6-11 and 6-12). Gas production also commences in year 7
(1989) , peaks at 691,200 mmcfd in years 13 through 16 (1995 through 1998),
and ceases in year 34 (2016) (Tables 6-10 and 6-13).
6,4 Facility Requirements and Locations
Facility requirements (platforms, pipelines, terminals, etc.) ancl related
construction scheduling are summarized in Tables 6-6 through 6-10.
scenario assumes that all oil and gas production is brought to shore
single crude oil terminal and LNG plant,, respectively, both locatecj at
Nome.
The major facility constructed is a) The terminal is designed to handle
This
to a
Cape
crude oil terminal located at Cape Nome.
the estimated peak production of about
128
750,000 bpd from the three “clusters” of fields. The terminal completes
crude stabilization, recovers LPG, treats tanker ballast water, and provides
storage for about 10 million barrels of crude (approx~mately 14 days pro-
duction). Terminal configuration includes buried pipelines to a two-berth
loading platform located approximately
These berths are designed to handle
transport crude to the U.S. west coast.
four kilometers (2.5 miles) offshore.
70,000 to 120,000 DWT tankers that
The tankers are conventional tankers
reinforced for Bering Sea ice; ice-breaker support for these tankers is
required.
The other major facility, also located at Cape Nome, is a LNG plant designed
to handle the estimated peak gas production of nearly 700 million cubic feet
per day. The LNG plant is a modularized barged-in facility and has a single
berth loading platform designed to handle 130,000m3 LNG tankers. A fleet
of three tankers transports the L.NG to the U.S. west coast. With a loading
frequency of six to seven days, storage capacity for about ten days of LNG
production is provided at the plant.
●
A forward service base supporting construction and operation of the Norton
Sound fields is constructed adjacent to the Cape Nome facilities. Field
construction is also supported by storage and accommodation barges and
freighters, moored in Norton Sound, and a rear supp,ort base located in the
Aleutian Islands.
The exploration phase of petroleum development in Norton Sound involves
aerial support and light supply transshipment provided by Nome, storage●
barges and freighters moored in Norton Sound, and an Aleutian Island storage
and transshipment facility,
6.5 Manpower Requirements
Manpower requirements associated with this scenario are shown in Tables 6==15
through 6-18.
129
. .
Aa1-0i-
v-l
● ☛ ☛
alma**AOv. -tSF- I--I(u OJrl
w
L&
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L
iio”
-1
dc$.
-.-)
., I rK !.3.r>
,/.
:.1 .,8,-
?,.-. ‘;
.4:.
. . . .._- __. ,_____ .
,.
6.00ml
. .co
● ☛
. .23
. . . .f.. -?L.
r..... .=;. . . .-.
+.. .
● ✎ ✎ ✎
r.r?.. .=--. . . .
. ..-. = . . . ..) 111,., L-JU
-I .- .,.. .
., . .. ..-[, ./$
,, ...--------.-. .!.J-- -.
J- J
132”
d*
G
J7
u
-1
N
0
>
r
n
r
;
--l
.,
.
: 0“
.a-Y
.,az
..
. .>-
. .--->
. .J ---
,., .. . - ..-
.. ...
.>
:0
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.-. -
..0.::-...-, ,L.e. --
s ‘.1:r
0 . . ..:
“\ .--..l\
. . .&&. ...>J, .> J... r’ ,,
. . &.-, A
:; ;
-
133. . .
—TABLE 6-17 (Attachment)
LISTOF TASKS BY ACTIVITY
Activity1
2
3
4
5
6
7
8
9
10
Service Bases
Task 1 -Task 2 -Task 5 -Task 6 -Task 7 -Task 8 -Task 11 -Task 12 -Task 13 -Task 20-Task 23-Task 24 -Task 27 -Task 28-Task 31 -Task 33 -Task 37 -Task 301 -
ONSHORE
(Onshore Employment - which would include allonshore administration, service base operations,rig and platform serviceExploration Well DrillingGeophysical ExplorationSupply/Anchor 8oats for RigsOevelo~ent DrillingSteel Jacket Installations and CommissioningConcrete Installations and CommissioningSingle-Leg Mooring SystemPipeline-Offshore, Gathering, Oi 1 and GasPipeline-Offshore, Trunk, Oil and GasGravel Island ConstructionSupply/Anchor Boats for PlatformSupply/Anchor Boats for Lay BargeLongshoring for PlatformLongshoring for Lay BargePlatform OperationMaintenance and Repairs for Platform and Supply BoatsLongshoring for Platform (Production)Gravel Island Construction
Hel icopter ServiceTask 4 - Helicopter for RigsTask 21 - Hel icopter Support for PlatformTask 22 - Helicopter Support for Lay BargeTask 34 - Helicopter for Platform
Construct ionService Base
Task 3 - Shore Base Construct ionTask 10 - Shore Base Construct ion
Pipe CoatingTask 15 - Pipe Coating
Onshore PipelinesTask 14 - Pipeline, Onshore, Trunk, Oil and Gas
TerminalTask 16 - Marine Terminal (assumed to be oil terminal)Task 18 - Crude Oil Pump Statfon Onshore
LIIG PlantTask 17 - LNG Plant
Concrete P1 atform Construct ionTask 19 - Concrete Platform Site PreparationTask 20 - Concrete Platform Construct ion
Oil Terminal OperationsTask 36 - Terminal and Pipeline Operations
Activity11
12
13
14
15
16
OFFSHORE
=2Geophysical and Geological Survey
RiJpTask 1 - Exploration Mel 1
PlatformsTask 6 - Development Dri I‘Task 31 - Operat ionsTask 32 - Workover and Wel
i ng
Stimulation
Platform InstallationTask 7 - Steel Jacket Installation and CommissioningTask 8 - Concrete Installation and CommissioningTask 11 - Single-Leg Mooring SystemTask 20 - Gravel Island construct ionTask 301 - Gravel Island Construction
Offshore Pipeline ConstructionTask 12 - Pipeline Offshore, Gathering, Oil and GasTask 13 - Pipeline Offshore, Trunk, Oil and Gas
Supply/Anchor/Tug BoatTask 5 - Supply/Anchor Boats for RigsTask 23 - Supply/Anchor Boats for PlatformTask 24 - Supply/Anchor Boats for Lay BargeTask 25 - Tugboats for Installation and TowoutTask 26 - Tugboats for Lay Barge SpreadTask 29 - Tugboats for SLMSTask 30- Supply Boat for SLMSTask 35 - Supply Boat for SLMS
LNG Plant OperationsTask 38 - LNG Operations
mw
Y.
u.@
a
(AlIA
J?
J
. ..
.
n.(- L,
.,-!2-23-:.1{12. .
-, :5-.
135. . . .
) 6.6 Environmental Considerations
The potential impacts of petroleum
as well to the high find scenario.
exploration discussed in Section 5.6 apply
Here, however, the anticipated construc-
tion of onshore and offshore pipelines introduces the potential for strong,
negative impact on salmon populations and shore nesting seabirds and waterf-
owl . The pipelines paralleling the coast between Rocky Point and Cape
Rodney, to Cape Nome intersect eight important salmon strearrts. Between ilome
and Cape Rodney is found extensive migrating waterfowl habitat. The bluffs
between Nome and Rocky Point are the established nesting grounds (with
associated offshore feeding areas) of common murres, black-legged kittiwakes,
horned puffins, thick-billed murres, and other seabirds. Strong environ-
mental regulations and stipulations may heavily constrain pipeline construc-
tion in this area.
Construction of extensive facilities at Cape Nome may demand greater gravel
resources than the area can supply. Removal of gravel from salmon streams
should be carefully regulated.
The routing of offshore pipelines to Cape Nome should minimize the loss
of navigable area in fishing zones, and potential for fishery resource
loss in the event of oil spill.
Drilling south of Cape Nome
productivity and diversity,
sistence king crab fishery.
will likely occur near areas of high benthic
which may have negative impact on the sub-
Efforts should be made to avoid localized
points of high density or diversity when drilling sites are chosen.
During the production phase, ice leads artificially maintained along vessel
routes and around well sites may attract seals and walruses, leading to
unnatural opportunities for impact. The Canadian petroleum development
experience in the Beaufort Sea may provide some guage of the potential for
this situation.
136
7.0 MEDIUM FIND SCENARIO
7.1 General Description
The medium find scenario assumes modest discoveries of oil and non-associated
gas. The basic characteristics of the scenario are summarized in Tables 7-1
and 7-2, The total reserves discovered and developed are:
Oil (MMBBL~
1,200
Five oil fields comprise
of fields, one in inner
of Nome, plus a single
Non-Associated Gas (BCF)
2,300
.the total reserves. They are located in two grotips
Norton Sound, the second in the c’entral sound south
field in the outer sound southwest of Cape Rodney
(Figures 7-1 and 7-?). The gas reserves are contained in two fields located
close to each other about 48 kilometers (30mi?es) south of Nome.
All crude is brought to a single terminal located at Cape Nome. For the
inner sound fields, this involves a 100-kilometer :62-mile) onshore pipeline
segment from Cape Darby to Cape Nome; the trunk pipeline from the central and
outer sound fields makes landfall close to the terminal site and therefore,
involves minimal onshore pipeline construction.
The non-associated gas fields share a single trunfi pipeline to a LNG plant
located adjacent to the crude oil terminal at Cape Nome.
7.2 Tracts and Location
The discovery ttacts and field locations (designated by OCS protraction
diagram numbers) are given in Table 7-3. The productive acreage cited
relates to the optima? recoverable reserves per acre assumed for the scenario
analysis.
e
*
*
9
*o●
137-—-. -. ..-_ . ,. .—. _—.
—
TABLE 7-1
MEDIUM FIND OJL SCENAR 10
TrunkFieldSize Number of
PipelineInitial Well “Peak
Oil Reservoir Depth-Pipeline Distance Diameter Shore
:MN8BL)Platform Product fon Product ivity Product ton Hater Depth to Shore Terminal (inches) Terminal
Location Meters Feet Production System No./Type* Wells (! J/L)) oil (MB/D) Meters Feet Kilometers Miles oil Location
[200 inner 2,286 7,500 Gravel island nith lG 40 2,000 76.8 18 60 133 14 Cape
Sound83
shared pipeline to
1
UOmeshore teminal
200 Inner 2,286 7,500 Gravel island with lG 4C 2,000 76.8 18 60 146 91 14 CapeSound shared pipeline to Nom
shore terminal
[
500 Central 2,286 7,500 Steel plat~orms with 2 s 80 2,000 153.6 18 60 34 21 18 CapeSound shared pipeline to Nome
shore terminal
250
(
Central 2,286 7,500 Steel platform with 1s 40 2,000 76.8 21 70 58 36 CapeSound
18shared pipeline to Nomeshore tennina?
250 Outer 2,286 7,500 Steel platform with 1s 40 2,000 76.8 30 100 95 18 CapeSound
59shared pipeline to Nomeshore terminal
* S = Ice reinforced steel platform.G = Caisson retained gravel island.
Fields in same bracket share trunk pipeline.
Source: Dames & Moors
TABLE 7-2
ME411Uf4FI Nil NON-ASSOCIATED GAS SCENARIO
+i4Q
SizeGas Reservoir Depth, PI atfoms(BCF) Location 14etersl Feet Production System No./Type*f-
!’300 “;’I 2“8’1’’5001= s:::’ I “
9
* S = Ice reinforced steel platform.
Fields in bracket share same trunk pipeline.
Source: Dames & Moore
Numbe’r OfProduction
Wells
16
16
Initial WellP@uct iv ity
(MWCFDI
15
15
PeakProduct ion Mater Depth;as (WFD) Met ers Feet
240 20 66
240 18 60
0 UP
Pipeline It o ShoreKilometer:
44
32
stancenninalRiles
30
20TTrunk
~ipel ine)iameter[i;m~s) L N G
P? ant
20 CapeNome
20 CapeNome
9*
*
U.T73’FW=-PH=I=H=-% Y
I .:L..” t !1; , . ( ... -,.-,.-.. ,
Figure 7-1 ~ MEDtUM FIND SCENAR\OFIELD AND SHOREFACILITY LOCATIONS
CENTRAL & OUTER NORTON SOUND
011 Field(Reserves in MMBBL)Gas Field(Reserves in ECF)
Crude Oil TerminalLNG PlantService B a s e
Pump Station orCompressor StationOil Pipeline CorridorGas Pipeline Corridor
IN
,0 Miles Z.o 3 0
i$lgmeterso 10 30 40 50
Figure f‘2 I M=UIWM rlmw =-=~anlu
FIEI.D ANO St+OR~FACILITY LOCATlONSINNER NORTON SOUNDS
Legend
o011 Field[Reserves In MMf38Ll
laeA
---0--
Crude OH Terminal
LNG Plant
Service Basepump Station orCompressor Station
oft Plpeiine Gorrlder
Gae Plpellne Corr/dor
i-i’-’’-’’-’-’’’-y”__“-%’=+%,.. ,., ,,, -,., ,.. . . . ,. . .. —.-. .,, -.,.-+.,, ,“==
I “-----3$4~ ..- :.: ------- -.;:W-..* “S’!...z ~.--.,+,.+ -K
. . ~-. .“!.. -tin % “. -.-=”.% ”..O..s - -’ ”. .-:,=.-. J:.”,
.:..-~-.g-.:-:-. ~..(.--~-l~m[- ~m, .,. :”, ,.!, p -“”-. . . . . . . . . . —z-. . ., . . . al “’” ! “’”! ““ ! ““ !’ “’” ! - ! e ! ?:1 ‘::”L--- .:_ . #
:,. ,+. , .,, ,.:.- $-+f [y---- .’”’.,,, - . . . . . ~.,.. ~’
+.x:, --+ ,.. , ‘‘ /...,
* -.;:;!,: fi,x,~”’’:;,qti$””:-... - “’ , >
& q~~:
“& - .#D:%;-:- ;.%-=~”-”: .;;”<,?,,’ ~$J& :#f?~~$# .
—;” - t.,, . .,w& *- -. . .- . . . . . ~..” .“ .,.
----
- ‘a ;.. ;<:’ :’:.-zr”-”- /- ..- ”,,,,
1-’- ‘ -‘ -‘ -’ -’”-’”-’”= =- W’’’”L=-=L=’-=’ -WR’’”-’-’’”-’-” -’”-’?-%$-=”==:-”- “’ . .f -y : ,“:
. .. . ..,,.=,. ‘( ~.,.,, ,.,
,.
;1. . ..-.
—.
j A+--W-,. := ~ =LJ-=LJ=.U. -EL-J -i -:! - i -i~ -./fj-. --,-- —.-
.- -
<“i . . ._< ..+...<. J .>. , . ..-t.+..,... . .-,..
., -”’.
~- )“- “ “w&!:.. .*.-’ . . .e“+: -. --.,--’
.,
,) --
.
:., . .. . . .
+’ -’”’\ 4./-.
“!;:?-, . , 7 : , . : . ,;:, .,
.
14.1
●
*
— ---------- . . ..- .-—.- —---_ . . . . . . . ..-
Location
Inner Sound
Inner Sound
Central Sound
Central Sound
Outer Sound
Central Sound
Central Sound
FielOil (mmbbl)
200
200
500
250
250
.-
--
TABLE 7-3
MEDIUM FIND SCENARIO - FIELDS AND TRACTS
SizeGas (bcf)
. .
--
-.
--
--
1,300
1,000
Acres’
3,333
3,333
8,333
4,167
4,167
4,333
3,333
Hectares
1,349
1,349
3,373
1,686
1,686
1,754
1,349
No. ofTracts 2
0.6
0.6
1.5
0.7
0.7 -
0.8
0.6
OCS Tract Numbers’
903, 904
967, 968
773, 774, 775, 817, 818
857, 858
802, 803, 846
952, 953, 996
823, 866, 867
] Recoverable reserves in the scenario are assumed to be 60,000 barrels per acre for oil and 300 mmcf for non-~ssociated gas.
A tract is 2,304 hectares (5,693 acres).‘ Tracts listed include all tracts that are involved in the surface expression of an oil or gas field. In somecases only portions (a corner, etc.) of a tract are involved. However, the entire tract is listed above. (SeeFigure 7-1 and 7-2 for exact tract location and portion involved in surface expression of fields.)
Source: Dames & Moore
7.3 Exploration, Development, and Production Schedules●
Exploration, development, and production schedules are shown on Tables
7-4 through 7-14. The assumptions on which these schedules are based are
given in llppendix Band E.t
Exploration commenc~~ in the first year after the lease sale (1983), peaks in
year 3 with 16 wells drilled, and terminates in the seventh year with a total
of 64 wells drilled (Table 7-4). Seven commercial discoveries are made (five
oil, two non-associated gas) over a five year period (Table 7-5). The
exploration involves jack-up rigs and drillships (in the outer sound) and
limited use of summer-constructed gravel islands in shallow water (15 meters
~50 feet] or less) where suitable borrow materials are either adjacent to the
well site or within economic haul distance.. Economics dictate extension of
the drilling season from the four to six month open-water season to a maximum
of eight months; this is accomplished by the use of ice-breaker support.
Field construction commences in year 4 after the decision to develop the
first discovery (a 500 mmbbl reserve oil field in central Norton’ Sound)
and the first platform is installed in year 5 (Table 7-6). Development
drilling commences the following year and the first oil production is
brought to shore in year 7 (1989) (Table 7-7), Offshore construction
activity peaks in year 6 when four platforms are installed, The favored
development strategy is ice-reinforced steel platforms; two caisson-retained
grave? production islands are, however, constructed in the inner sound to
develop the two 200 mmbbl oil fields. The last platform is installed in
year 8.
Oil production from Norton Sound commences in year 8
lease sale, peaks at 463,000 b/d in year 12 (1994), and
(2011) (Tables 7-11 and 7-12). Gas production commences
peaks at 460.8 mmcfd in years 12 through 18 (1994 throughin year 28 (2010) (Tables 7=.11 and 7-13).
(1990) after the
ceases in year 29in year 7 (1989),
2000), and ceases●e
143. . . . . . . .._—-. — .—. .—.
—
WellIYE!KExp.l
Del.2
TOTAL
TABLE 7-4
EXPLORATION SCHEDULE FOR EXPLORATION AND DELINEATION WELLS - MEDIUM FIND SCENAR1O
Jells
11
3
14 IL6
4
2
8
Year After I ?ase Sale ~ -8
+ ‘“:‘ens 7 “ 9’ ‘e’”Rigs Wells
4 4
2 2
4 4
—r------
ZRi sWells
1 In this high find scenario a success rate of one significant discovey for approximately every eight exploration wells is assumed. This is slightlyhigher than the average lD percent success rate in U.S. offshore areas in the past 10 years and significantly higher than the average of the past fiveyears (Tucker$ 1978).
2 The number of delineation wells assumed per discovery is two field sizes of less than 500 imnbbl oil or 2,000 bcf gas, and three for fields of500 mmbbl oil and 2,000 bcf gas and larger.3 An average comp~etion time of four months pre exploration/delineation well ‘s a$sumed. The drilling season is assumed to be extended to a maximumof eight months by ice breaker support. In addition, the limited use of summer-constructed gravel ,islands to extend drilling into the winter is also. .postulated. -
Source: Dames & Moore
Year AfterLease Sale
I
2
2
3
3
“4
Type
Oi 1
Oi 1
Gas
Oi 1
Oil
Gas
l-!--
TABLE 7-5
TIMING OF DISCOVERIES - blEQILIM FIND SCENARIO
ReserveOil (mmbbl)’
500
250
..-
200
250
. .
L_!.1
SizeGas (bcf)
.-
.-
1,300
--
.-
1,000
Location
Central Sound
Central Sound
Central Sound
Inner Sound
Outer Sound
Central Sound
WaterMeters
18
21
20
18
30
18
1---18
Assumes field has low GOR and associated gas is used to power platform and reinfected.
Source: Dames & Moore
e*
* ● *
!?fM&-
60
70
66
60
100
60
60
●0 *
TABLE 7-6
PLATFORM CONSTRUCTION AND INSTALLATION SCHEOULE - MEDIUM FIND SCENARIO
Field Year After Lease SaleLocation Oi 1 (FU4BBL) Gas (BCF) 1 2 3 4 5 6 9 10 11 12
Inner Sound 2D0 -- * D AG
Inner Sound 200 - - * D AG
Central Sound 500 -.. * D As As
Central Sound 250 .- * D As
Outer Sound 250 .- * D AS
Central Sound -- 1,300 * D AS
Central Sound -- 1,000 * D AS
DTALS l(s) l(G) I(G) l(s)3(s) 1(s)
* = Discovery; D = Decis~on to Develop; AS = Steel Platform; AG = Gravel Island
Notes:
1. Steel platform installation is assumed to begin in June in each case; gravel island construction starts the year after decision todevelop’and takes two summer seasons.2. Platform “installation” includes module lifting, hook-up, and commissioning.
Source: Dames & Moore
TABLE 7-7
DEVELOPMENT WELL DRILLING SCHEDULE - MEDIUM FIND SCENARIO
No.z of TotalField Dril 1 Rigs No. Of Start of
Oi 1 Gas PI at forms Per Product ion Other Drilling Year After Lease Sale - No. of Wells Dril led3Location (MMBBL) (BCF) Nos. Type 1 Platform Wells Wellsh Month 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17
nner Sound 200 - - 1 G 2 40 8 April AG 12 16P 16 4 w
nner Sound 200 -- 1 G . 2 40 8 April liG 12 16P 16 4 w
entral Sound 500 - - s 2 40 82
Apt-i 1 M 12 16P 16 4 M
s 2 40 8 Apri 1 As 12 16P 16 4 w
entral Sound 250 -- 1 s 2 40 8 Apri 1 As 12 16P 16 4 w
luter Sound 250 -- 1 .S 2 40 8 APr$ 1 AS 12 16P 16 4 w
entral Sound -- 1,300 1 s 1 Apri 1 As 6P 8 2
entral Sound -- 1,000 1 s 1 Apri } AS 6P 8 2
OTALS 12 46 80 88 64 26 4
1 s = Steel; G = Gravel‘Platforms sized for 40 or more well’ slots are assumed to have two drill rigs operating during development drilling. Platforms sized for less than40 well slots are assumed to have one drill rig operating during development drilling.
3 Drilling progress is assumed to be 45 days per well.q Gas or water-injection wells etc. , well allowances assumed to one well for every five oil production wells.
A’S = Platform arrives on site -- assumed to be June; platform installation and commissioning assumed to take 10 months.AG = Gravel island construction starts June 1 the year after decision to develop and takes two summer seasons.W = Work over commences -- assumed to be five years after beginning of production from platform.P = Production starts; assumed to occur when first 10 oil wells are completed or first four gas wells.
Source: Dames & Moore
o● ● ●
8*
TABLE 7-8
EXPLORATION AND PRODU~TION GRAVEL ISLANDS -MEDIUM FIND SCENARIO
Exploration Number ofYear After 7.5 Ill 15 m ConstructionLease Sale (25 ft) (50 ft) Production Total Spreads
1
2 1 1 1
3 1 1 . 1
4 1 1 2
5 1 1 2
6 1. 1, 2 2
7 1 1 1
8
9
10
TOTALS 1 4 2 7 N/A
Note: Arrows show exploration islands expanded and modified for production.
148
?-4
.-Nsl-l
m “e-mm-l
co !0m
w
m
N
.
iii
149.-
—
TABLE 7-10
MAJOR FACILITIES CONSTRUCTION SCHEDULE - MEDIUM FIND SCENARIO
Peak Throughput Year After LeaFaci 1 ity ’/Locat ion Oi 1 (MBD] Gas (NMCFO) 1 2 3 4 6
Cape Nome Oil Terminal 436 -- *
Cape Nome LNG Plant -- 461 4
Cape Nome Support Base(permanent ) (medium) -4-s* T
11 2
1 Assume construction starts in spring of year indicated.wma Source: Oames & Moore
Location
Inner Sound
Inner Sound
Central Sound
“Central Sound
L-Outer Sound
Central Sound
Central Sound
Fi (Oil
J!&!%!_
200
200
500
250
1-250
. .
--
“ GasQQQ_..-
--
.-
-.
--
.-
1,300
1,000
TAfsLE 7-11
FIELD PRODUCTION SCHEDULE - MEOIUM FIND SCENAR1O
Peak PrOil
.__.@Q_
76.8
76.8
153.6
76.8
76.8
.-
--
iuctionGas
-@lZQ._
--
.-
--
--
.-
230.4
230.4
YProduct ionStart Up
9
10
7~
9
7
9
r After Lease SaleProduct ion PeakShut Down Production
I28 12
29 13
26 10-11
21 10-12
22 11-13
27 9-18
28 12-18
Years ofProduction’
20
20
20
14
14
21
20
‘ Years of production relates to the date of st?rt tip frcm firzt installed platform (multi -platfonu fields); production shut downoccurs at same time for all platforms.
Source: Dames k Moore
e P ● ● ●●
●
TABLE 7-12
MEDIUM FIND SCENARIO PRODUCTION BY YEAR FOR INDIVIDUAL FIELDS AND TOTAL - OIL
PRODUCTION IN MMBBL YEAR BY FIELD SIZE (MMIWL)Calendar Year After Inner Sound Central Sound
YearOuter Sound
Lease Sal e zoo 200 500 250 250 Totals
1983 1
1984 2
1985 3
1986 4
1987 5
19Ba 6
1989 7 7.008 7.008
1990 8 24.528 7.008 7.008 31.536
1991 9 7.008 45.552 17.520 7.008” 77.088
1992 10 14.016 7.008 56.064 28.032 17.520 122.640
1993 11 21.024 14.016 56.064 28.032 28.032 147.168
1994 12 28.024 21.024 54.005 28.032 28.032 159.125
1995 13 27.050 28.032 46.354 27.982 28.032 157.450
1996 14 22.401 27.050 38.598 24.906 27.982 140.937
1997 15 17.432 22.401 32.168 20.647 24.906 117.554
1998 16 13.897 17.432 26.840 17.116 20.647 95.932
1999 17 11.000 13.897 21.420 14.187 17.116 77.620
2000 18 8.886 11.000 18.757 11.763 14.187 64.593
2001 19 6.835 8.886 15.221 9.751 11.763 52.456
2002 20 5.250 6.835 12.703 8.084 9.751 42.623
2003 21 4.154 5.250 10.616 6.701 8.084 34.805
2004 22 3.286 4.154 8.886 6.701 23.027
2005 23 2.600 3.286 7.452 13.338
2006 24 2.057 2.600 6.263 10.920
2007 25 1.628 2.057 5.328 9.013
2008 26 1.288 1.628 4.417 7.333
2009 27 1.019 1.288 2.307
2010 28 0.837 1.019 1.856
2011 29 0.837 0.837
2012 30
2013 31
2014 32
2015 33
2016 34
Peak 011 Product ion = 436,000 b/d.
Source: Dames & Moore
I
152
TABLE 7-13
. MEDIUM FIND SCENARIO PRODUCTION BY YEAR FOR INDIVIDUAL FIELDS AND TOTALNON-ASSOCIATED GAS
PRODUCTION IN BCF YEAR BY FIELO SIZE (BCF)Calendar Year After Central Sound
Year Lease Sale 1300 1000 Totals
1983 11984 21985 31986 4
1987 51988 61989 7 26.280 26.2801990 8 63.072 63.0721991 9 84.096 21.024 105.1201992 10 84.096 42.048 126.1441993 11 84.096 63.072 147.1681994 12 84.096 84.096 168s1921995 13 84.096 84.096 168.1921996 14 84.096 84.096 168.1921997 15 84.096 84.096 168.1921998 16 84.096 84.096 168.1921999 17 84.096 84.096 168.1922000 18 84,096 84.096 168.1922001 19 76.846 72.423 149.2692002 20 61.980 54. L22 116.1022003 21 49.936 40.521 90.4772004 22 40.265 30.710 70.5752005 23 32.454 22.672 55.1262006 24 26.157 16.958 43.1152007 25 21.002 12.685 33.7722008 26 16.992 9.488 26.48020D9 27 13.696 7.097 20.793201D 28 5.309 5.3092011 292012 302013 312014 32
2015 33
2016 34
0●
●
.●
Peak Gas Production = 460.8 MMCFD.
Source: Oames & Moore
●153
..— — ---. ..-— ,_ ”,. -. --—. — - -- -—.. —
TABLE 7-14
MAJOR SHORE FACILITIES START UP AND SHUT DOWN DATES -MEDIUM FIND SCENARIO
Year After Lease SaleFacility Start Up Datei Shut Down DateZ
Cape Nome Oi? Terminal 6 29
Cape Nome LNG Plant 7 38
‘ For the purposes of manpower estimation start up is assumed to beJanuary 1.z For-the purposes of manpower estimation shut down is to be December 31.
Source: Dames & Moore
I
154
7.4 Facility Requirements and Locations
●
oFacility requirements (platforms, pipelines, terminals, etc.) and related ●construction scheduling are summarized in Tables 7-6 through 7-10. This
scenario assumes that all oil and gas production is brought to shore to a
sing?e crude oil terminal and LNG plant, respectively, both located at Cape
Nome, for processing and transport to the lower 48 by tanker. ●
The major facility constructed is a medium-sized crude oil terminal, located
at Cape Nome, designed to handle the estimate peak production of about
460,000 b/d. (Original ly, after discovery the 500 mmbbl field, a smaller aterminal is planned but with furthe,r significant discoveries in the following
two years, plans for a larger facility are made). The terminal completes
crude stabilization, recovers; LPG, treats tanker ballast water, and provides
storage for about 6 million barrels of crude (approximately 14 days produc-
tion). Terminal configuration includes buried pipelines to a two-berth
loading platform located approximately four kilometers (2.5 miles) offshore.
These berths are designed to handle 70,000 to 120,000 DWT tankers that
●
transport crude to the U.S. west
reinforced for Bering Sea ice;
docking facilities is required.
coast. The tankers are conventional tankersa
ice-breaker support for these tankers and
The other major facility, also located at Cape Nome, is a LNG plant designed
to handle the estimated peak gas production of about 460 million cubic feet
per day. The LNG plant is a modularized barged-in facility and has a single
berth loading platform designed to handle 130,000m3 LNG tankers. A fleet
of three tankers transports the LNG to the U.S. west coast. With a loading
frequency of approximately once a week, storage capacity for about ten days
of LNG production (4.5 BCF) is provided at the plant.
A forward service base supporting construction and operation of the Norton
Sound fields is-constructed adjacent to the Cape Nome facilities. Field
construction is also supported by storage and accommodation barges a n d
freig
Aleut
ters, moored in Norton Sound, and a rear support base located in the
an Islands.
●
155
. -. .
●
) The exploration phase of petroleum development in Norton Sound involves
aerial support and light supply transshipment provided by Nome, storage
barges and freighters moored in Norton Sound, and an Aleutian Island storage
and transshipment facility.
The exploration phase of petroleum development in Norton Sound involves
aerial support and light supply transshipment provided by Nome, storage
barges and freighters moored in Norton Sound, and an Aleutian Island storage
and transshipment facility.
7.5 Manpower Requirements
Manpower requirements associated with this scenario are shown in Tables 7-15
through 7-18.
7.6 Environmental Considerations
1 Discussion of the impacts associated with the medium find scenario may be
drawn from the high find case, where applicable. Thus, the onshore pipeline
from Cape Nome to Rocky Point will traverse established seabird colonies at
Bluff and five major salmon streams. Precautions against disturbance of
these resources will be required. Thou,gh comparatively reduced, the require-
ments for gravel in the Nome area will likely strain local resources and
further destruction from gravel mining may result. Other impacts, resulting
from exploration, drilling, and construction of gravel islands, are as
discussed in Sections 5.6 and 6.6.
156
YEAR AFTEI+ PETRoLEIJMLKA>L >ALC LW~>llUKC
.16!90: 34bf7 .3 3984 e4 2988.5 1096.6 2004.7 569?2.8 10176.9 13W0.
12.288*.:: 9096.12 7788.13 7s]20
8172.!: 8352.16 0352.]7 8352.]8 8352,19 8 3 5 2 .2 0 8352.21 8352.22 7308.23 6.?64.24 6264.25 626+ .26 6264.27 3996 e2H 2952.29 ]044.30 0.
●o*
uNbnuw
166.366.416.312.IA2.212.518.912.1128.960.6]8.420.384.384.304.384.394.384.384.3W+ *384.336*288.288*288-288 w192.144.48*
o .
●
TABLE ,7-15
ONSXTE MANPOWER REQUIREMENTS BY 1NDUSTR%
CONST6’KICTION
I!ONSII’E 6-tAN-bIONTHSD
‘---””-’”’- ONSHOREUPP>HUHt
0.600.800.800.
2025.7900.4300.5475.3117.2784e31372*3168.3168.316&.3]68.31b8e3~68,3]68.3~68.3168.3168.3072e2976.2G7~,2976e2976e2784.2b88 .2496.2 4 0 0 .
0.30.60.,
3396.8697.3091?375.
4487.814.564.852.948.948.948.948*948.948.948.948.948.948.852.756.756.756.756.564.468.276.180.
●
TRANSPORTATIONOFFSHORE ONSHORE
624 e1456.1664.1248.969.
3290.1236.1639 e1245.1152.1152.1152.1152.1152.1152.1152.1152.1152.1152.1152.115241008.864.866.%64 .864.576.432.144.
0.
168*392.448.336.329.
1228.1596.1843.1857e1872.1872.1872i!872.i872.1872.1872.1872.1872,1872.1872.1872e1764.1656.A656.] 656.1656.1440.1332.108.
o*
w GONSHORE
0,0.0.0 .0 .0.
. 720.7 2 0 .7!?0.7 2 0 .720.720.7 2 0 .7 2 0 .720.7 2 0 .720.7 2 0 .7 2 0 .7 2 0 .7 2 0 .72o.7 2 0 .7 2 0 .7 2 0 .7 2 0 .720.
09O*0 .
*
ALL INDUSTRIESOFFSHORE ONSHORE
2243.5342.6448.5036.4090.13194.1122s.17290.17002+16224.13320.12108.12132.12492.12672,126?2.12672.12672.12672.12672.126?2.11388.10104.10!04.loio4*10104.7356*6072.3684.2400.
334.786.924.
404499!38.4531.3209.7962.4520.4AA6.4062.3960.3924.3926.3924.3924,3924.3924.3924.3924.3924.3672.3420.3420.3420.3420.2916.1944.632.180.
TOTAL
2577.6126.7372.9080.B3229.17726.14437.25252.22322.20340.t7382.16068.16056.~6fb~6.!6596.t659b.16596.16596.16596,16596.i6596,15060,13524.13524.13524.13524.10272.8016.4116.2550.
MEDIuM FIND SCENARIO09/26/79
JANUA2YYEAR AFTERLEASE SALE
12345b789
101112131415161718192021222324252627282930
TABLE 7-16
JANUARY, JULY AND PEAK MANPOUER{NUMBER OF PEOPLE)
OFFSHORE OhSliOtiEONSITE OFFSITE O N S I T EOFFSITE
O*o .0.0 .0 .
254.1296.928.1674.1520.1320.1093*1011.1041.1056.1056.1056.1056.1056.1056.1056.949.842.8 4 2 .842*842*613.506a3 0 7 .2 0 0 .
0.0 .0 .o*0.
215.1126.8i)4.1493.1372.1172.945.863.893.908.908.908.908.908.908.908.807.706.706.706.706.489.388.201.100.
0.0.0 .0.
696-584*376.2 5 3 -.770.361,361s3 3 9 .3 2 7 .327,3 2 7 ,327-32793 2 7 -3 2 7 ,327.327.306.2?85.285.2ti5 .285.2 4 3 .162036*1 5 .
0.0 .0 .o*
77.66.182.
166.230.1(36.1B60186.1M6.1860ld6.186.!86.186.1FJ6.186.186.181.!7b.176.176.176.166.101.
7.2.
JANUARYTOTAL
0 .0 .0.0 .
773.ll18c2980 ●
2151.+16703439 ●
3039.2563,2387.244 ~-2477.2477-2477.2417e2477*2477,[email protected] 0 0 9 .2009.2009,1511*11s7.5 5 1 .317.
REQUIREMENTS
JULYOFFSHORE
ONSITE OFFSITE
296.849*931.742-6 6 8 .9 7 7 .985-866 ●
420.296 ●
040.98].
1011.1041.1056-1056*1056.1056.1056-1056.1056.949.842*84.2.842.842,613.506.307.200.
207.S83.652m5 1 4 .453.
15260768*
15600127M.1146-892,8 3 3 .a63.893*908-908.9 0 8 .908.908.9 0 8 .908,8070706.706,7 0 6 .706.489.386.
“201.100.
ONSHOREONSITE O F F S I T E
43.112.125s371.859*376.244 ●
9 0 8 .332m3 3 7 .3 3 1 .327.3 2 7 .3 2 7 .3 2 7 .327.3 2 7 ,327.327.3 2 7 ,327.30602 0 5 ,285.285*2&5,243.162.36.1 5 .
15.3 7 .42-62*
103*55.
1s7.2 3 8 .181.186.1 8 6 .186.1 8 6 .1 8 6 .1 8 6 .186.186*186.1 8 6 .1 8 6 .186*181.176.1 7 6 .1 7 6 .1 7 6 .166.1 0 1 .
7 ..2*
JULYTOTAL
561-1581-1750.1689-2083,3 9 3 3 *?134.4 5 7 3 .321A*2967*2449-2327-2387e244702 4 7 7 .2477-2477-2477.2477-2477s2 4 7 7 .2243620096200902 0 0 9 .2 0 0 9 -1511.1157.
5 5 1 .3 1 7 .
PEAK
MONTH TOTAL
5 588.6 1581,6 1750.9 1937,6 2121,6 4100.1 2980,6 4573,1 4167.1 3439.1 3039.
2563.I 2307,1 2447,1 2477.
2477,: 2477.1 2477,1 2477,
2477*: 2477,1 2243.
2009s: 2009.1 2009.1 2009,1 15110
1157,: 551.1 317,
TABLE 7-17
YEARLY MANPOWER REQUIREMENTS $’U ACTIVITY
09924/79
{MAN-MONTHS)
4 5 10VEAR/ACTIVITY
1 ONSITEoFFSITE
2 ONSITEL)FFSITE
3 ONSITEOFFSITE
4 ONSATEoFFSITE
5 ONSITEOFFSITE
.6 ONSITEOFFSITE
7 ONSITEoFFSITE
8 ONSI TEoFFSITE
9 ONSITEoFFSITL
10 ONSITEOFFSITE
11 ONSITEOFFSXTE
12 ONSI TEoFFSITE
63 ONSITL(JFFSITE
14 0N5ATEoFFSITE
15 ONSSTEoFFSITL
1
2B4.00
506.3*
604.7.
4b5.7.
508.20e
1965.86.
t301e41.
]951.56.
1967.2b,
1908.20.
1854.20.
1752.20.
8716.20.
1716.20.
1716.20.
2
12001!20”.
260.2 8 0 .
3 2 0 .320.
260.24oe
115.1156
260.e260.
iao.180.
305e3 0 5 .
435.4 3 s .
480.k80.
680.&Bi36
480.4800
680.480s
480.480.
460.4 8 0 ,
3
0.O*
0.0.
0.o*
1600.176.
500.55.
0.0.
000.
0.0.
0000
O*0.
0.o*
0.0.
000.
0.0.
0.0.
b
O*Q*
0.0.
0.0.
3“730.191.
7006,771.
930.102.
0.0.
o*0.
c.0.
0.0.
0.0.
0.0.
0.0.
0.0.
0.0.
7
0.0 .
0,0.
o*0.
!).0.
1009.Ill.
1009*ill.
o*0.
0.o*
c,0.
0.o*
0.0.
0.0.
0.0.
0.0.
0.00
8 9
0. 0 .O* 0.
0.’ 0,0. 0.
O* 0.0. 0.
0. o*O* 0.
0. o*0. 0.
0. 0.0. 09
0, 1008.o* 1008.
0. 1008.0. 10080
Il. 1006so. loofl.
0. 1008.0. 1008.
o* 1008.0. iooa.
0. 100800. 1008.
0. 1008.0. 1008.
o* 1008.0. 1008.
0. AO08.0. 1008.
P
11
275.0.
350 *0.
4 0 0 .00
3 0 0 .0.
2 0 0 .0.
100a0.
100.0.
o*0.
0.0.
0.O*
0.0.
0.0.
0.0.
0.0,
0.0.
14
0.o*
4 0 0 .200.
800.400.
800.400.
2 0 2 5 .1625.
7025.6225.
4 3 0 0 .3 2 0 0 .
4425 e2625.
2925.1725.
2400.1200.
2400.1200.
2 4 0 0 .L200*
2400.1200.
24oO.1200.
2400.1 2 0 0 .
●
is
o*o .
o*0.
0.o*
0.0 .
080.
0.0.
0.0.
o*0.
0 .0.
0,0.
0.0 .
720 e720.
720 e720.
72o.720.
720.720.
72o.720.
720.720.
720.720.
72o.7.20.
720.720.
●
1344. 0.1344. 0.
3136.3136. &
3584* 083584. 0.
2608. 0 .2688* 0.
896. “ Oe8 9 6 . 0.
8 9 6 . 1oo$.896. 1008.
1456.728.
1664.8 3 2 .
0 .0 .
0 .il.
0.00
0.0 .
0 .0.
0,0.
12413c624 ●
9 6 9 .485.
0 .0.
0 .0 .
875-1375.
0.o*
368.4 0 .
0400
a57.9 4 .
0.0 .
0.0 .
3290.1645s
o*0.
3120.343e
29C.43.
0.0.
0 , 5 5 9 2 .0. 5!592.
0 .0 .
1050,1050.
1236.618.
1639.020.
o* 13440.0. 13440.
0. 122aa.0. 12288.
0 .0 .
0.0 .
12!45.623.
1152.576,
0 .o*
0.0 .
0.o*
0.00
1152.576,
1152.576.
o*00
09o*
0 . 9096.0. 9096.
0. 77aa.o* 7788.
0 .0 .
0.0.
0.0 .
0 .0.
0.0.
0.0.
0.o*
o* 781?.0 . 7S12.
0.0 .
1152.576.
0. a17200. 8172,
0 . 8352.0 . 8352.
1152.576*
1152.5 7 6 .
0 .0 .
0 .0 .
0.0.
** SEE A ‘ CHEO KEY OF ACTIVITIES
*a
● * ● ●
. —
MEOI/UM FIND SCENAR!O09/24/79 TARLE 7-17 (Cent. )
YEARLY MANPOWER R.ECNJIREMENTS BY ACTIVITY(MAN-MONTHS)
7
0 .0 .
0.O*
0.0 .
o*0 .
0 .0 .
0 .0 .
0 .0.
0 .0 .
.
;:
0 .0 .
Oeo .
o*o .
0 .0.
0 .0 .
0 .0 .
12
0 .0 .
o*o*
o .0.
o*0 .
0,0.
o*o .
0,0.
0 .0 .
0.0 .
0 .0 .
0 .0 .
0 .o*
o .0 ,
0 .0 .
0 .0 .
13 14 ]5
o .0 .
0 .o*
0 .0 .
0 .0 .
0 .0 .
0 .0 .
0 ,0 .
0 .0 .
0 .0 .
0 .0 .
0 .0 .
o*o .
0 .0 .
0 .0 .
o*o .
lb **
11s2.5 7 6 .
1152.5 7 6 .
115205 7 6 .
1152.5 7 6 .
1152.5 7 6 .
1152.5 7 6 .
1008.5 0 4 .
8 6 4 .4 3 2 ,
8 6 4 .4 3 2 .
8 6 4 .4 3 2 .
864.632.
5 7 6 .286.
4 3 2 .216.
14L.72.
0 .0,
5
0 .0 .
0.O*
0 .o*
000 .
o*0.
0 .0.
090.
0.o*
~.0.
0,o*
0,0 .
000.
0,0 .
O*0.
o*o*
a
o .0 .
0.O*
0.o*
o*o*
o*0 .
o*o .
o*o .
o*00
G .o*
‘o ●
0 .
0 .0 .
0 .0 .
000 .
0 .
9
100a.1008.
1008.1008*
1008.1008.
1008.1008.
1008*1008.
1008.1008.
1008.1008.
1008.10080
1008e1068.
1008.10080
100801008.
1008.1008.
1008.1008.
o*0.
0 .0 .
10
7 2 0 .7 2 0 .
7 2 0 .7 2 0 .
7.20.7 2 0 .
7 2 0 .720.
7 2 0 .72oe
7 2 0 .72o.
7 2 0 .7 2 0 .
7 2 0 .7 2 0 .
7 2 0 .7 2 0 .
7 2 0 .7 2 0 .
7 2 0 .720.
7 2 0 .7 2 0 .
0 .0 .
o*0 .
0 .0 .
11
0.0.
0.0.
0.0.
O*0.
0.0.
0.0.
o*00
o*0.
(1.0.
0.0.
0.0.
0.0.
0.0.
0.0.
0.0.
YEAR/ACTIVITY 1
1716.209
1716.209
1716.20.
171b.20.
1716.20.
1716.20.
1524.20.
133i’.20.
1332.20.
1332.20.
1332.20.
948.20*
756.20.
372.20.
100..20.
i?
4 8 0 .4 8 0 .
4 8 0 .4 8 0 .
4 8 0 .480.
4 8 0 .4 8 0 .
4 8 0 ,4 8 0 .
4 8 0 .4 8 0 .
420.4 2 0 .
3 6 0 .3 6 0 .
3 6 0 .3 6 0 .
3 6 0 .3 6 0 .
36u.3 6 0 .
2 4 0 .240e
180.~80.
60.60.
0.0.
3
o*o.
0.0.
0 .0.
o*0.
0.0.
090.
0.0.
0 .0 .
0.o*
0.0.
0.0.
0.o*
o .o*
0.o*
o*o*
4
0 .o*
0,0.
o*O*
0.09
0.00
0.o*
0.0 .
0.0.
‘o.o*
0.0.
0 .00
0.0 .
o*0 .
0.o*
o*o .
6
0 .0 .
0.0.
0 .09
090 .
0 .0 .
0 .0 .
O*0 .
0 .O*
c.o .
0 .0.
(1.0 .
0 .0 .
0 .0 .
080.
0.o*
ONSilEuFFSITE
ONSITEI)FFSITE
ONSIILoFFSITE
ON.51TEOFFSITL
ONSITEOFFSITE
ONSIIEOFFSITE
ONSITEOFFSITL
ONSITEt)FFsI TE
ONSITEOFFSITE
ONSIKEOFFSgTE
ONSI?EOFFSITE
ONSITEoFFS~TE
ONSITEUFFSITE
ONSIIEOFfSl lE
ONSIIE(JFFSITE
8352.8352.
8352,8352.
2 4 0 0 .1200.
2400.1200.
8352.8352.
8352.8352,
2 4 0 0 .1200.
2400.1200.
19
8 3 5 2 .8 3 5 2 .
8 3 5 2 .8 3 5 2 .
7 3 0 8 .7 3 0 8 .
6 2 6 4 .6 2 6 4 ,
2400.1200.
2400.1200.
2400.1200.
2400.12004
2400.1200.
20
23
24
25
26
27
2 8
29
30
6 2 6 4 ,6 2 6 4 .
6 2 6 4 .6 2 6 4 .
6 2 6 4 ,6 2 6 4 ,
3 9 9 6 .~996.
2 9 5 2 .2’952.
2 4 0 0 .1200.
2 4 0 0 .1200.
2400,1200.
2 4 0 0 .1200.
1044.1044,
0.o*
2 4 0 0 .1200.
2 4 0 0 .1200.
0 .
0s0 .
4 0 S E E ATTACHEO KEY OF ACTIVITIES
Act iv i ty1
2
3
4
5
6
7
8
9
10
Service Bases
Task 1 -Task 2 -Task 5 -Task 6-Task 7 -Task 8 -Task 11 -Task 12 -Task 13-Task 20-Task 23-Task 24 -Task 27 -Task 28-Task 31 -Task 33 -Task 31 -Task 301 -
TABLE 7-17 (Attachment)LIST OF TASKS ftY ACTIVITY”
ONSHORE
(Onshore Employment - which would include allonshore administration, service base operations,ri 9 and platform set-viceExploration Hell OrillingGeophysical ExplorationSupply/Anchor Boats for RigsOevel ofxnent Ori 11 i ngSteel Jacket Installations and CommissioningConcrete Installations and Cotmnissioni ngSi ngl e-Leg Mooring SystemPipeline-Offshore, Gathering, Oil and GasPipeline-Offshore, Trunk, Oil and GasGravel Island Construct ionSupply/Anchor Boats for PlatformSupply/Anchor Boats for Lay 8argeLongshori ng for PlatformLongshoring for Lay BargeP1 atform OperationMaintenance and Repairs for Platform and Supply BoatsLongshoring for Platform (Production)Gravel I S1 and Construction
Hel icopter ServiceTask 4 - Helicopter for RigsTask 21 - Helicopter Support for PlatformTask 22 - Helicopter Support for Lay 8argeTask 34 - Helicopter for Platform
ConstructionService Base
Task 3 - Shore Base ConstructionTask 10 - Shore Base Construction
Pipe CoatingTask 15 - Pipe Coating
‘ Onshore PipelinesTask 14 - Pipeline, Onshore, Trunk, Oil and Gas
TerminalTask 16 - Marine Terminal (assumed to be oil terminal)Task 18 - Crude Oi 1 Pump Stat ion Onshore
LNG PI antTask 17 - LNG Plant
Concrete Platform ConstructionTask 19 - Concrete Platform Side PreparationTask 20 - Concrete Platform Construction
Oi 1 Terminal Operat ionsTask 36 - Terminal and Pipeline Operations
LNG PI ant OperationsTask 38 - Llffi Operations
Activity11
12
13
14
15
16
.
OFFSHORE
5y&2- Geophysical and Geological Survey
~Task 1 - Exploration Mel 1
PlatformsTask 6 - Development OrillingTask 31 - OperationsTask 32 - Workover and Wel 1 Stimulation
Platform InstallationTask 7 - Steel Jacket Installation and CommissioningTask 8 - Concrete Installation and Commissioning -
Task 11 - Single-Leg Mooring SystemTask 20 - Gravel Island constructionTask 301 - Gravel Island Construct ion
Off shore Pipeline Construct ionTask 1 2 - Pipeline Offshore, Gathering, Oil and GasTask 13 - Pipeline Offshore, Trunk, Oil and Gas
Supply/Anchor/Tug BoatTask 5 - SuD~lY/Anchor Boats for RimTask 23- ‘- ‘-Supply/Anchor Boats for Pl~tformTask 24 - Supply/Anchor Boats for Lay BargeTask 25 - Tugboats for Installation and TowoutTask 26 - Tugboats for Lay 8arge SpreadTask 29 - Tugboats for SLMSTask 30 - Supply Boat for SLMSTask 35 - Supply Boat for SLMS
;. ,,.
1.!kDILI14 FIND SCENARIO05/24/79 TABLE 7-18
SUMt4AHlf OF MANPO#ER REi3UlREMENTS FOR ALL INDUSTRIES
ONSITEYEAR AFTER (MAN-MONTHS)------- - ..- ---- ---- oFislioRE
2 2 4 3 .5 3 4 2 .6 4 4 8 .5 0 3 6 .4 0 5 0 .
13194.11228.17290.17802.16224.13320.12108.12132.12492.12672.~2b7c?e12672.12672.12672.12672.12672.11388.10104*JO1O4*!0104010104.7356.6072.3684.2400.
336.786.9 2 4 .
4 0 4 4 .913804531.3209.7562.4520.4H16.6062.396o.3924.3924.39Z4 .3924.3924.3924.3924.3924.39.24*3672.3420.342o.3420.342o.2916.1944.4 3 2 .180.
TOTAL
2577.612!j.7372.9080.
]3229.17726.~4437.25252.22322.20340.17382.16068.16056.16416.165’26.16596.16596.16596.16596.16596.]6S96.15060.13524.13524.13524.13524.10272.8016.4116.2560.
TOTAL lNCLUOES ONSITE ANO OFFSITE
ONSITE AND TOTAL O*
TOTAL(MAN-MONTHS)
OFFSHORE ONSHORE
3 8 9 9 .9 4 0 6 .
11264.0746.7(195*
2 3 8 4 3 .20638.32161.33702.30672.2 4 8 6 4 .2 2 4 4 0 .22488.2320&.2 3 5 6 6 .2 3 5 6 8 .2 3 5 6 8 .2 3 5 6 6 .23S68.2 3 5 6 8 .2 3 5 6 8 .21072.18576*18576.1 8 S 7 6 .16576.13224*1072Ho609b,sbOO.
4 5 4 .1069.1251.4 6 5 6 .
AO21O.5132.5 1 5 8 .
]0489.6751.6344.6 2 9 0 .6188.6152.6152.6152.6152.b15206152.6152.6152.6152.S840.5~2b .5528.5528.552tI.4 9 0 4 .3 1 5 2 .5A2.200.
TOTAL
4 3 5 3 .10475*12515.13406.173Q6.2 8 9 7 5 ..?5796.426&9.40532.3 7 0 1 6 .3 1 1 5 4 .28628.2 8 6 4 0 .2 9 3 6 0 .2 9 7 2 0 .2 9 7 2 0 .2 9 7 2 0 .2 9 7 2 0 .29720.2972o.2 9 7 2 0 .2 6 9 1 2 .2 4 1 0 4 .2 4 1 0 4 .2 4 1 0 4 .24104.18128.13680.b608.3800.
TOTAL MONTHLY AVEHAGE(NUMBER OF PEOPLE)
OFFSHORE ONSHORE
325. 3fl.784. 90.939. 105.729. 389.592. 851.
1987* 428.1720. 430.2680. 874.2816. 563.2556. 529.2072. 525.]fJ70. 516.1874. 513.1934. 513.196&. S13.1964. 513.1964. 513.1964. 513.1964. 513.1964. 513.1964, 513.1756. 407.1548. 461.1548. 461.154s. 461.1540. 4bl.1102. 409.b9& . 263.Sotl. 43.300. 17.
TOTAL
3 6 3 .8 7 3 .
1043.111801443*2415.2150.3555.3378.3085.2597.2386.2387.24&7 .2477.2477.2477.2477.2477.2477.2477.2243.2009.2009.2009.2009.1511.1157.551.317.
8.0 LOW FIND SCENAR1O
8.1 General Description
The low find scenario assumes small commercial discoveries of oil and
non-associated gas. The basic characteristics of the scenario are summarized
in Tables 8-1 and 8-2. The total reserves discovered and developed are:
Oil (MMBBL) .Non-Associated Gas (BCF)
380 1,200
These reserves, especially the gas, are barely economic to develop. The oil
reserves comprise two fields located between 34 and 58 kilometers (21 and 36
miles) southwest of Nom~ while the non-associated gas reserves occur in a
single field located about 34 kilometers (21 miles) south of Nome (Figure
8-1). No discoveries are made in the inner or outer sounds (Figures 8-1 and
8-2] .
Two trunk pipelines, both about 34 kilometers (21 miles) long, transport the
oil and gas production direct to a crude oil terminal and LNG plant, respec~-
ively, located at Cape Nome. Minimal onshore pipeline construction is
involved in the development of these fields.
8.2 Tracts and Location
l%e discovery tracts and their locations (designated by OCS protraction
diagram numbers) are given in Table 8-3. The productive acreage cited
relates to theoptimal recoverable reserves per acre assumed for the scenario
analysis.
8.3 Exploration, Development, and Production Schedules
Exploration, development, and production schedules are shown on Tables 8-4
through 8-14. The assumptions on which these schedules are based are given
in Appendix B and E.
163
—
TA8LE 8-1
LOW FIND OIL SCENAR1O
TrunkFteld PipelineSize Number of Initial Well Peak Pipel ine Distance Diameter ShoreOil Reservoir Depth
[MNBBL)Pl at forms Product ion Product ivity Production Water Depth to Shore Terminal (i fi~s) Terminal
Location Meters Feet Production System No. /Type* Wells (IvD) oil (Mtvo) Neters Feet Kilometers Miles Location
[
200 Central 2,286 7,500 Steel platform with Is 40 2,000 76.8 21 10 3$ 21 14 CapeSound shared pipeline to Nome
shore terminal
1 BO Central 2,286 7,500 Steel platfotn with is 40 2,000 76.8 21 10 58 36 14 CapeSound shared pipeline to Nome
shore terminal(
*S= Ice reinforced steel platform.
Fields in same bracket share trunk pipeline.
. .
Source: Dames & Moore
.EFieldSt zeGasBCF Location
1,200 Central‘ Sound
I?eservoi r DepthMeters 1, k eet Production System
I I2,286 7,500 Single steel platf-orm with unsharedpipeline to l.NGp] ant
* S = Ice reinforced steel platform.
Source: Dames & Moore
TA8LE 8-2
LOW FIND NON-ASSOCIATED GAS SCENARIO
PeakProduct ionGas (MMCFD~
240
. . .
!,:‘+’ ,- , ‘, -i-, : ‘y-s ‘ ---=.--—l -- .“- ”.-, “ .* .“~--r .+--- ..#-----= .--~ -,!,
W~zE::5:-:?3:?:?~=~’-_~_.+. >. .:.. “~ . ...<-...~.+;;~;;”~” :x. ,“- ..:...:.-: i-; :,-,,6 -;” .~- ,;- ,:+./.:- ; .-,.
, --- J. .. J71-- - . . —— .- —-—.”*= ------ ,- , ,-,- ”. :..,..., . ..4-1...!-, .-,--. ,.$,- .-’’*,-,-,- ~.—-.~.;; -, .-,”,. - -.”,,
‘*. . . .:- ---. .--: ~ : --, ,:- —-—---- ; -~-—m—--—- - - - ,“ ,- , ,“ ,- ,“ ,“.- - .- ,-:-l=--.~-~ “:--” ...”,--- .,- .—— —----- .-—.
+4 ,, ,.—.. . .— ..-. .--—. .- . ..-.= —-- ----—.+,. - - . ---!-.:- :g5z:g::;:”z::;;:.:-:-:z-.;:.==-.-:-=::-:--”:
‘F“.!”.”.”,”. -0..
! i~....=~.-=-.x~~.~..-- - - ,. . x ..~m - s -, . ,. - \ ,. ‘ .,. . . .. —-. . . . . . . . -.. —. .-— -s., ,U ,”..*,” -— -..,,. . . “.1,._._. ~.. -L_-... ... . . . . . . . . . . . . . -~ -i, .- ,,
-,.~-,... .. :..-..; --!-’- ““”. ’”.’....- “.”. ”-”-.””-” - . ,“..:.= := ~= “-. * .-.+O: ,...~ ‘ :- . . . . . . . . . . . .A..i ----+- .- -yi. --- . . . . . -. . . . . . .—. ----~-k - - ---,.-)..-!- ,... ” . . .. $.-.” .- .-”.---:.- ---’---: -!-
!,,*-**- - ,, .-----.:- ,- :& J. *--e-.,-. .- ., -s -. . .-.. . . -------- ‘... .;.. . . .y .4. -.. —
-~> L;;>” ..:j.zt “ ‘....!-l-i- -:;::
-r-) -”~-t - ~-~~--i-t”--l’ -:’-’ 0’ -1-1””- \-. C TT. i... ; .% t :.. i ..l.:~ _ ~ ~ _~.~-f.w!. [ f_ f... Jt-.t i ~ [ ~ 1 l.wl. A!=!.., f"!w:.a ~~i-!.- '.= f.=t=!,m.ja '..am ia; .:
~-~:{.. ‘~’- -- ::: -~-’-n. --;ti_-.~_..=-= N s. EA j t . ...1 _l, _l ,: L“. .- ’ - ’ - - - “-”-” ~--- “----- “-” ” - - - t - - - i-!-
~-[=~-:- ?=-fs:w -z-”= ’a--” --v”a -“.-- ..”-..””.,-. -.. ----~n:..;~-l”e-:>:
.. :”=?-’”-””. :“. ””. ”” m”.-.” . - . ” - ,
i ‘l-
.! . . . ..+— - - - - - - -.. =’..’”’ . . - - - - - ““’ -””-- -. -!-,-- ,-i-. . . . ~~.=..a.r . . . ...’... ‘ . ..’..’..- “.”’......”- “---- .7 :— .J+y... ”. ”..!----- ‘.”:..’-””-”- .-’.
. . . . . . . “.... -.”,- . . . . . . . . , . , . . . . -L-. - - - -“.---’: - . . . ..’—.— . . ” . . ” - ” - - -
./
- “ . . ” . . . . . . . . ” . - - ” . -= -,-~ - -. . ..-. .. ..!.’--=-- “ - ’ - - . - ” - - -“. ””.-.,.- -.,, - - - - .,, -..--”’ - - - - - - - --.” “.. -:=!r:-
,--- ~ f;.“-. ‘ . . ’ - ’ - - - - - “ - . . , - - - - - - - - - - - - - - ” - - - - - ..-. .-= .e~ ~-=
-oL-
&: - -’-=.. 2 +;+- -..,.,”, --- ,,,--”w -,. - -k:.. . . . . . . . ----. --......:- -.-% - , - .;*>.
------ . . . .. ’..’.”.’- .- . ..”.’...- ‘-. ’=-”-’ ------ ----- ---. . * - —7 .-<
. . ..—. . .
n
IN
-@-III
v
igure 8-Z L(3W FtNO SGt=NAR10F{EL.~ ANO SHOREFACILITY LOCATIONSINNER NORTON SOUND
L,egend
aoil Field(Reserves in MMEBL)
tGas Field
~-_-:J (Reserves in 6CF)
m ~r~de ON Terminal
@ L.NG Plant
A Segvice Bsse
@pump station ofCompfessO~ Station
.
.
I ,. - -’--’”.”=. ““.:=--”,
- . ” ’ - - - - ‘-”’-”-”- -o”.”-. . .
I ..-. .m ””... “.”.”.”--”- -’--. .. . . . . . . ..’ . . . .- -. -. ,.” -. - ‘- .9”- .” ..6
1
..**XT%!
*
*
9
●
●o
. .. —.- ----.. —-= —
— —
TABLE 8-3
LOW FIND SCENARIO - FIELDS AND TRACTS
Field SizeLocation
No. ofOil (mmbbl) Gas (bcf) Acres p Hectares Tracts 2 OCS Tract Numbers’
Central Sound 2 0 0 -- 3,333 1,349 0.6 773, 774, 817, 818
Central Sound 180 -- 3,000 1,214 0.5 903
Central Sound -- 1,200 4,000 1,618 0.7 866, 867
‘ Recoverable reserves in the scenario are assumed to be 60,000 barrels per acre for oil and 300 rnmcf for non-associated gas.2. A tract is 2,304 hectares (5,693 acres).‘ Tracts listed include all tracts that are ifivolved in the surface expression of an oil or gas field. In somew
o-l cases only portions (a corner, etc.) of a tract are involved. However, the entire tract is listed above. (Seem Figures 8-1 and 8-2 for exact tract location and portion involved in surface expression of fields.)
Source: Dames & Moore
TABLE 8-4
EXPLORATION SCHEDULE FOR EXPLORAT ION AND DEL iNEATiON MLLS - LOW F i ND SCENAR iO
Year After Lease SaleWel.i 1 i 2 3 ’ 4 5 6 7 8Type
9 10 Wel }Rigs Mensa Rigs Wells Rigs Wells Rigs Wells Rigs wells Rigs Wells Rigs Wel 1s Rigs Wells Rigs Uells Rigs Wel 1s Totals
Exp : 2 4 6. 5 9 54
‘1 25
306
Del.23
4 2 . 6
TOTAL 4 6 9 11 5 2 36
1 In this high find scenario a success rate of one significant djscovey for approximately every 10 exploration wel Is is assumed. This is consistentwith a tO percent success rate in U.S. offshore areas in the past 10 years although higher than the average of the past five years (Tucker, 1978).2 The number of delineation wells assumed per discovery is two field sizes of less than 500 mmbbl oil or 2,000 bcf gas, and three for fields of500 mmbbl oi 1 and 2,000 bcf gas and larger.3 An average cornplet ion time of four months pre exploration~del i neat ion wel 1 is assumed. The dri 11 ing season is assumed to be extended to a maximum
of eight months by ice breaker support. In addition, the 1 imited use of summer-constructed gravel islands to extend ciri 11 ing into the winter is alsopostulated.
Source: Dames & Moorewcl-l@
@
—
TABLE 8-5
TIMING OF DISCOVERIES - LOW FIND SCENARIO
Year After Reserve Size Water DepthLease Sale T y p e Oil (mmbbl)k Gas (bcf) Location Meters Feet
2 Oi 1 200 .- Central Sound 21 70
2 Oi 1 180 -- Central Sound 16 54
3 Gas -- 1,200 Central Sound 21 70
‘ Assumes field has low GOR and associated gas is used to power platform and reinfected.
Source: Dames & Moore
TABLE 8-6
PLATFORM CONSTRUCTION ANO INSTALLATION SCHEDULE - LOW FIND SCENARIO
,Fielii Year After Lease Sale
Location Oil (NMBBL) Gas (BCF) 1 2 3 4 9 10 11 ! 12
Central Sound 200 -- * D A$
Central Sound 180 - - * D A-s
Central Sound ..- 1,200 * D As
OTALS 2(s) 1(s) 1(s) ‘
* = Discovery; D = Decision to Develop; AS = Steel F’latfonn
Notes:
1. Steel platform installation is assumed to begin in June in each case; gravel island construction starts the year after decision todevelop and takes two summer seasons.2. Platform “installation” includes module lifting, hook-up, and ccxnmissioning.
Source: Darnes & Moore
●o
9 ● ‘ * 9
—
I
TABLE 8-7
DEVELOPMENT WELL DRILLING SCHEOULE - LOW FIND SCENARIO
No. a of Tot alField Drill Rigs No. Of Start of
Platforms Per Produt;on Other OrillingLocation (MM;;L) (%) Nos. Type L P1 atform
Year After Lease Sale - No. of Wells Orilled’Wells’, Mont h 1 2 3 4 5 1 0 11 12 13 15 16 17
central Sound 200 - - I s 2 40 8 Apri 1 4s 12 16P 16 4 w
Central Sound 180 - - 1 s 2 40 8 Apri 1 As 12 16P 16 4 w
:entral Sound - - 1,200 1 s 1 Apri 1 &s 6P 8 2
l_OTALS 24 38 40 10
‘ S = Steel‘ Platforms sized for 40 or more well slots are assumed to have two drill rigs operating during development drilling. Platforms sized for less than!O well slots are assumed to have one drill rig operating during development drillin9. .
Drilling progress is assumed to be 45 days per well.* Gas or water injection wells etc., well allowances assumed to one well for every five oil production wells.AS = platform arrives on Site -- assumed to be June; platform installation and commissioning assumed to take 10 months.W = Work over commences -- assumed to be five years a$t~t- tieyinninyP = Production starts; assumed to occur when first 10 oil wells are
Source: Oames & Moore
uf production t’rcmcompleted or first
plationn.four gas wells.
TAt3LE 8-8 m
Year AfterLease Sale —
1
2
3
4
5
6
7
8
9
10
TOTALS
EXPLORATION AND PRODUCTION GRAVEL ISLANDS -.LOW FIND SCENARIO
-7&#(25 ft)—
1
1
1
3
Production
o
Total
Number ofConstruction
Spreads _—
N/A●
173
TABLE 8-9
—
~2c4-0
—
alL0KInc3
.
Pipeline Diameter(inches)
Oi 1 Gas1
14
12
14
ubtot al
14
ubtotal
PIPELINE CONSTRUCTION SCHEDULE - LOW FINO SCENARIO - KILOMETERS (MILES) CONSTRUCTED BY YEAR
Mater De t h
T
Meters Feet
0-18 0-60
18 60
0-18 0-60
III
10
Year After Lease Sale
1 2 3 4 5 6 7 8 9 11
31 (19)
24 (15)
31 (19)
86 (53)
3 (2)’
3 (2)
6 (4)
92 (57)
Source: Dames & Moore
TABLE 8-10
MAJOR FACILITIES CONSTRUCTION SCHEOULE - LOW FIND SCENARIO
r
Facility ’/LocationPeak Through~ut Year After Lease Sa eOil (MBD) Gas (MMCFD) 1 2 3 4 5 6 y ~ ‘9 lo ~1 12
Cape Nome Oil Terminal 153.6 - -+ +
CaP@ Nom@ LNG P?ant -.. 230.4>
Cape Nome Support Base( p e r m a n e n t ) (small ) ~
* Assume construction starts in spring of year indicated.
Source: Dames & Moore
e* ‘* ●
.
* *e *
—
TABLE 8-11
FIELD PRODUCTION SCHEOUIE - LOU FIND SCENARIO
Field Peak Production Year After Lease SaleOi 1 Gas Gas Production Product ion Peak
(Mill)Years of
Location (MMBBL) (BCF) (MMCFD) Start UP Shut Down Production Product ion 1
Central Sound zoo - - 76.8 -- 8 27 11 20
Centra~ Sound 180 -- 76.8 -- 8 22 11 15
Central Sound .- 1,200 -. 230.4 8 32 11-19 25
‘ Years of production relates to the date of start up from first installed platform (multi-platform fields); production shut downoccurs at same time for all platforms.
Source: Dames & Moore
TABLE 8-12
LOU FIND SCENARIO PRODUCTION BY YEAR FOR INDIVIDUAL FIELDS AND TOTAL - OIL
PRODUCTION IN MM88L YEAR BY FIELD SIZE (MMBBL)Cal endar Year After Central Sound
Year Lease Sale zoo 180
19B3 11984 21985 31986 41987 51988 61989 71990 8 7.008 7.0081991 9 . 14.016 14.0161992 10 21.024 21.0241993 11 28.032 28.0321994 12 27.050 26.9621995 13 22.401 20.7881996 14 17.432 16.0281997 1 5 13.897 12.3571998 16 11.000 9.5271999 17 8.886 7.3462000 1 8 6.835 5.66.32001 19 5.250 4.3662002 20 4.154 3.3662003 21 3.286 2.5952004 22 2.600 0.92?2005 23 2.0572006 24 1.6282007 25 1.2882008 26 1.0192009 2 ? 0.8372010 282011 292012 302013 312014 322015 332016 34
Peak Oil Production = 153,600 b/d
Source: Dames & Moore
7Totals
--414.01628.03242.048
=-=-l54.01243.18933.46026.254
●
20.52716.23212.4989.6167.520
6.881
3.522
2.057
1.628
1.288
1.019
0.837
●e
●177
- . . . . ..—_— . . .. —. —.. —.- .—. —. .
.
[
TABLE 8-13
LOW FINO SCENARIO PRODUCTION BY YEAR FOR INDIVIDUAL FIELOS AND TOTALNON-ASSDC IATED GAS
PRODUCTION IN 8CF YEAR 8Y FIELD SIZE (BCF)Calendar Year After Central Sound
‘fear Lease Sale Totals
1983 1
1984 2
1985 3
1986 41987 51988 61989 71990 8 21.024 21.0241991 9 42.048 42.0481992 10 63.072 63.0721993 11 84.096 84.0961994 12 84.096 84,0961995 13 84.096 84.0961996 14 84.096 84.0961997 15 84.096 84.0961998 16 84.096 84.0961999 17 84.096 84.0962000 18 84.096 84.0962001 19 84.096 84.0962002 20 69.600 69.6002003 21 54.680 54.6802004 22 42.933 42.933.2n05 23 33.710 33.7102006 24 26.468 26.4682007 25 20.782 20.7822008 26 16.317 16.3172009 27 12.812 12.8122010 28 10.059 10.0592011 29 7.888 7.8882012 30 6.193 6.1932013 31 4.862 4.8622014 32 3.817 3.8172015 332016 34
\
Peak Gas Production = 230.4 MMCFO.
Source: Dames & Moore
178
TABLE 8-14
MAJOR SHORE FACILITIES START UP AND SHUT DOWN DATES -LOW FIND SCENARIO
Year After Lease SaleFacility Start Up DateJ Shut Down Date’—. — .
Cape Nome Oil Terminal .8 27
Cape Nome LNG Plant 8 32
L
1 For the purposes of manpower estimation start up is assumed to beJanuary 1.2 For the purposes of manpower estimation shut down is to be December 31.
Source: Dames & Moore
*
e’
1798
I Exploration commences in the first year after the lease sale (1983), peaks in
year 4 with 12 wells drilled, and terminates in year 6 with a total of 36
wells drilled (Table 8-4). No discoveries are made until the second year of
exploration when two small oil fields southwest of Nome are discovered (Table
8-5) . The only commercial gas discovery
no further commercial hydrocarbon finds
involves jack-up rigs and drillships (in
is made in
are made.
the outer
year 3 (1985) after which
The exploration program
sound) and limited use of
summer-constructed gravel islands in shallow water (15 meters [50 feet~ or
less) where suitable borrow materials are either adjacent to the well site or
within economic haul distance. Economics dictate extension of the drilling
season from the four to six month open-water season to a maximum of eight
months; this is accomplished by the use of ice-breaker support.
The decision to develop the two small oil fields is ,made concurrently
in year 4. Single ice-reinforced steel platforms for each field are install-
ed 24 months later (Table 8-6). Development drilling commences in year 7 and
crude production is brought on line in year 8 (1990). Field construction to
develop the gas field starts with the installation of a single steel platform
in year 7 (1989) and gas production commences -;he following year (1990).
Oil and gas production from Norton Sound. both start in year 8 (19’30).
Oil production peaks at 153,000 b/d in year 11 (1993) and ceases in year
(2009) (Tables 8-11 through 8-12). Gas producti jn
years 11 through 19 (1993 through 2001), and ceases
8-11 and 8-13).
8.4 Facility Requirements and Locations
27
peaks at 230.4 mmcfd in
n year 32 (2014) (“Tab”es
Facility requirements (platforms, pipelines, terminals, etc.) and related
construction scheduling are summarized in Tables 8-6 through 8-10, As with
the high and medium find scenarios, this scenario also assumes that all oil
and gas production is brought to shore to a single crude oil terminal and LNG
plant, respectively, both located at Cape Ilome.
180
The major facility constructed is a small crude oil terminal located at
Cape Nome. The terminal, which is designed to handle the estimated peak
production of about 150,000 bpd, completes crude stabilization, recovers
LPG, treats tanker ballast water, and provides storage for about two million
barrels of crude (approximately 14 days production). Terminal configuration
includes a buried pipeline to a single-berth loading platform located approx-
imately four kilometers (2.5 miles) offshore. This berth is designed to
handle 70,000 DIIT tankers that transport crude to the U.S. west coast. The
●
tankers are conventional
support for these tankers
tankers reinforced for Bering Sea ice; ice-breakere
is required.
---
The other major facility, also located at Cape Nome, is a small LNG plant
designed to handle the estimated peak gas production of about 230 million
cubic feet per day. The LNG plant is a modularized barged-in facility and
has a single berth loading p?atform designed to handle 130,000m3 LNG
tankers. A fleet of two
With a loading frequency
15 days of LNG production
tankers transports the LNG to the U.S. west coast.
of once every ten days, storage capacity for about
is provided at the plant.
A forward service base supporting construction afld operation of the Norton
Sound fields is constructed adjacent to the Cape Nome facilities. Field
construction is also supported by storage and accommodation barges and
freighters, moored in Norton Sound, and a rear support base located in the
Aleutian Islands.
The exploration phase of petroleum development
aerial support and light supply transshipment
barges and freighters moored
and transshipment facility,
8.5 Manpower Requirements
Manpower requirements assoc’
through 8-18.
in Norton Sound, and
in Norton Sound involves
p r o v i d e d b y Nome, s t o r a g e
a n A l e u t i a n i s l a n d s t o r a g e
ated with this scenaro are shown in Tables 8-15
LOU FIND SCENARIO09/24/79
YEAti AFTER PETROLEUM
TABLE 8-15
ONSITE MANPOtJER REQUIREMENTS BY 1NDUSTR%{ONSITE MfiN-MONTliS)
CONSTRUCTION TRANSPORTATION MFGLCA5t >ALL Uttsnulic
1 9 9 6 .2 1494.3 1992.4 2988.5 996.6 498.7 2016.8 5’784.9 5952.
10 3936.11 2760.12 2592.]3 3132.14 313.2.15 3132916 3132.17 3132.18 3132.19 3132.20 3132.21 3132.22 3132.23 2268..24 2268.25 2178.26 2068.27 2088.28 1044.29 1044.30 1044.
UN5tlUKk
104.156.208.312,106s52.
216.486.S04*280.162.144.]44.1 4 4 .144.]44.144.]44.144.144*]44.144.
9 6 .96,9 6 .9 6 .96.4 8 .4 8 .4 8 .
Utt>liunt
o*400.800.800.boo.
24S0 .2800.525.
o*268.288.288.288.288.288.288.288.288.288.?88.288.288.192.192.!92.192.192.96.96,96.
UN>tlUKt
o.30.60.60.
938.1912.3461,
53*o.
288.288,288.28B.288.288.288,28R.288.288,288.288.288.192,;92.192.192.192.96.96,96.
UtP3HUKt
416*624 ●
832.1248.
4 1 6 .1314.1282.669.432.432.432.432.432.432.432.432.432.432.432.432.432.432.288.288.t?88*288.Z88.144.144.144.
112.168.224.336.1120490.496.801.708.708.708.708.708.708.708.708.708.70LI.708.708.708.706.600.600.600.600.216.106.108.106.
JN>HuHc
0.0.0.0.0.0.0.
4 6 0 .4 8 0 .4 8 0 .4 8 0 .4 8 0 .4 8 0 .48o.4 8 0 .4 8 0 .4 8 0 .4 8 0 .4 8 0 .480.4 8 0 .48o.4 8 0 .48o.4 0 0 .4 8 0 .4 8 0 .48o.4 8 0 .4 8 0 .
ALL INDUSTRIES(JFFSHORE ONSHORE
1412.2518.3624 ●
!3036.2212.4 2 6 2 .6 0 9 8 .6978.6 3 8 4 .4 6 5 6 .3480.3 3 1 2 .3852.3 8 5 2 .3852.3852.3852.3852.3852.3 8 5 2 .3852.3852.2748.2768.2658.2568.2 5 6 8 .1284.1284.1284.
216.354.492.708.
1154.2454.4173.1820.lb~c?.1764.1638.1620.1620.1620.1620.1620.1620.1620.A620.1620.1620.1620.1368.1368.1368.1368.964.732.732.732.
TOTAL
1628.2 8 7 2 .4116.5 7 4 4 .3 3 6 6 .6 7 1 6 .
10272.8 7 9 7 .8 0 7 6 .6 4 2 0 .5 1 1 8 .4 9 3 2 .5 4 7 2 .5472.5 4 7 2 .5 4 7 2 .5 4 7 2 .5 4 7 2 .5 4 7 2 .5 4 7 2 .5 4 7 2 ,5 4 7 2 .4116.4116.4 0 2 6 .3 9 3 6 .3 5 5 2 .2016.2 0 1 6 .2 0 1 6 .
~OW FXNLI 5cENARf009/?7?4/79 TABLE 8-16
JANUARY? JULY AND PEAK MANPOb’ER REQUIREMENTS
I
JANUARY6)FF5MJ?E ONSHORE
O N S I T E UFFSITE ONSITE
0.0.O*o*0.o*
!j08e7 3 0 .5 3 2 *556 a332.2 7 6 .321.3.21.3210321*321e321o321.321.32},32i*2 2 9 .229e229*214e2]4.107.107.107.
0.0.0.0.0.O*
429.673.S]4.538 *314.258.303.303.303.303.303.3030303.3030303.303.217.‘217*2E7*202.202.101.101.101.
0.0,0.0.O*0.
534.184.~41e165.141*135.135.135*135.1354135*135.135*35*35935*]4,14.14014*82.61.61.61.
DFFSITE
O*0909080 .O*
62.94*87.87*87.87.87.67.tll’.87.87.87.a7.8 7 .87*87.82,8 2 .
-432.8 2 .50.45.4 5 *45*
(NIJMBER OF PEOPLE)
d4NuARYTOTAL
0.0.o*0.o*0 .
1533.1680.1274.1346.8 7 4 .7 5 6 .046.846.8 4 6 .846.846.846.846,846.846.846..@~-642.642.612.548.314.314.314.
JULYOFFSHORE.-..,- --- OFFSITEUIY>:IC
189.471.570.742.3a9.590.738.532.532.332.276.276.32!.321.321*321.321,321.321.321.321.321.2.29.229.214.2A4.214.107.to7.107.
138.3(i7*376.514.238.498.656.514*5140314*258.258 *303.303.303.303.303.303.303.303.303.303.217.2]7.20202029202.101.101.101.
uNbtfunk.ONSITE O F F S I T E
28.56,71*97.!75.23tl.b46.]4!.141*141.135.135.a35*135.135.135.135,1350135.135*135.]35.]14.114.114.114.62.61.bl.61,
*
10.l?.22*32.26,33.50.87.87.87.87.87.87.87,87.87.87.87.87.87.87,87.82.82.82,82.50.45.45.65,
JULYTOTAL
365,85t.
10~7e1 3 8 5 .828*
1 3 5 9 ,1889.1274e1274.
8 7 4 .7 5 6 .?56.8 4 6 .8 4 6 .84&.8 4 6 .846.8 4 6 .8 4 6 .8 4 6 ,8 4 6 .8 4 6 .662.6 4 2 .612.6 1 2 .5 4 8 .3 1 4 .314.3!4.
MONTH
5666
1:61
!
111
PEAK
TOTAL
3 6 5 .851*
1o47.1412,
8 7 6 .1572.1932.1680$1274.1346.8 7 4 .756.8 4 6 .846.846.8 4 6 .846.846.846.846.866.846.642.642.6 4 2 .612.5 4 8 .314.314.314,
**
Luti FIND SCENARIO09/24/79 TABLE 8-17
YEARLY MANPOWER REQUIREt4ENTS BY ACTIVITY[MAN-MONTHSJ
“m-P
YEAN/ACIIVITY
1 ONSITEuFF51TE
2 0N51TEoFFSITL
3 ONSITE(JFFSI TE
4 ONSITEOFFSITE
~ ONSITEOFFSITE
6 ONSITEOFFSITE
7 ONSITEOFFSITE
8 ONSITELIFF5~TE
9 ONSITE”OFFSITE
“ 10 ONSITEOFFSITE
11 ONSITEOFFSITE
Ail! ONSITEoFFSITE
13 ONSIIEOFFSITE
14 ONSITLoFFSITE
15 ONSITEuFFSITE
1
136.0.
234.3*
332.7.
468.7*
196.7.
677.279
933.33.
76o.6.
648.0.
72o.O*
596.O*
576.0.
576.0.
576.0.
576.0.
2
60.’80.
i20.120.
160.160.
24o.240.
80.80.
110.110.
8(J.80.
]95.195.
]Mo.180.
180.lBO.
180.180.
180.180.
iao.180.
itio.180.
180.180.
3
o*o*
o.0.
o*o.
0.0.
878.97.
0.o*
o*o*
0.0.
0.o*
0.0.
o*o*
o.0.
0.o*
0.o*
o.0.
4
0.O*
0.o*
0.o*
o*0.
-o.0.
o*0.
368.40.
0.0.
o*0.
o*o*
o.o*
o.0.
0.0.
0.0.
0.0.
5
0.o*
o.0.
0.0.
0.0.
o*o.
0.0.
0.0.
0.0.
0.0.
0.0.
0.0.
0.o*
o*0.
0.0.
o*o.
6
o*o.
0.0.
0.0.
o*o.
0.().
109,2.120.
2418.266.
000.
0.o*
o.00
0.0.
0.0.
o*o*
o*u .
o .0 .
7
0.0.
0.0.
o*o*
o.0.
0.0.
575.63.
375*41.
0.0.
0.0.
o*00
0.0.
o*o.
0.0.
0.0.
0.0.
8
0.0.
0.0.
0.0.
0.O*
o.0.
o*o.
0.0.
o*o*
o.0.
0.O*
o.0.
0.0.
0.0.
o*o.
O*0.
9
0.0.
0.0.
0.o*
o.0.
0.0.
0.0.
o*o.
384*384.
384.364.
384.384.
3fj4.3a4.
386.384.
384.384.
384.3af+.
3d4.384.
10
0.0.
0.0.
0.0.
0.0.
0.0.
o*o.
0.0.
4 8 0 .4 8 00
4 8 0 .4 8 0 .
480.48o.
4 8 0 .4 8 0 .
4 8 0 .4 8 0 .
4 8 0 ,4 8 0 ,
4 8 0 .4 8 0 .
4 8 0 .4 8 0 .
11
100.o*
L5080.
200.0.
300.o*
100.0.
50.0.
0.0.
0.o*
o.0.
0.0.
0.0.
0.0.
0.0.
0.0.
0.0.
12
896.896.
1344.1344.
1792.1792.
2688.2688.
896.896,
448,448.
o*o.
0.0.
0.0.
0.o*
o.0.
0.0.
0.o*
o.0.
0.0.
13
o*o.
0.0.
0.0.
00o*
o.0.
0.0.
2016.2016.
5784.5784.
5952 ●
5952.
3936.3936.
2760.2760.
2592.2592.
3132.3132.
3132.3132.
3132.3132.
14
0.o*
400.200.
800-400.
8000400.
800,400.
2450-2450.
2275,2275*
525.525.
0.o*
o*0.
o*o.
0.0.
0.o*
o*o.
0.0.
15
0 .0 .
0 .0 .
0 .0 .
0 .0 .
0 .0 .
0 ,0 .
5.25.5 2 5 .
0 .0 .
0 .0 .
0 .o*
o .0 .
0 .0 .
0 .0 .
0 .0 .
0 .0 .
16 .+
4i6.208.
6 2 4 .312.
8 3 2 .416.
124a.624.
416.2 0 8 ,
1 3 1 4 .6 5 7 .
1282.6 4 1 .
6 6 9 .3 3 5 .
632.2 1 6 ,
43 .2 .2 1 6 .
4 3 2 ..216 .
43.?.216.
43.?.216.
k32.216s
43.?.216.
** SEE ATTACHED KEY OF ACTIVITIES
LOW FIND SCENARIO09/24/79 TARLE 8-17 (Cont. )
YEARLY MANPOtiEH rEQuIREMENTS BY ACTIVITYtMAN-t40NTHS)
YEAR/ACTIVITY
16 ONSITEuFFSITE
17 ONSITEoFFSITE
16 0NS17E0FF51TE
!9 ONSITEOFFSITE
20 ONSITEOFFSITE
21 O N S I T EO F F S I T E
i
576.o*
576.00
576.00
576..0.
576.o*
576.0.
2
180.180.
180.180.
A80.180.
180.100.
180.180.
180.180.
3
0.o*
000.
0.0.
0.0.
o*o.
o*o.
5
0.0.
0.0.
0.0.
0.0.
0.0.
0 ?.o*
7
0.0.
0.0.
0.0.
0.0.
0.0.
0.0.
0.0.
000.
o*o.
0.0.
0.0.
0.0.
0.0.
o*o.
o*o.
10
4 8 0 .4 8 0 .
4 8 0 .480.
480.4 8 0 .
4 6 0 .4 8 0 .
4 8 0 .4M0,
460.4 8 0 .
4 8 0 .4 8 0 .
4 8 0 .4 8 0 .
4 8 0 .4 8 0 .
480.480.
4 8 0 .4 8 0 .
4 8 0 .4 8 0 .
4 $ 0 .4 8 0 .
480.480.
4H0.480.
*
11
0.0.
0.0.
0.0.
o*0.
0.0.
0.0.
0.0.
0.o*
0.o*
o*0.
0.0.
0.0.
0.o*
o.0.
0.0.
12 13 ]4
o.0.
o*o*
o.0.
0.0.
0.0.
o*o.
0.0.
0,0.
0.0.
o*00
0.0.
0.0.
0.0.
0.0.
0.o*
@
15
0.0.
0.0.
0.0.
0.0.
0.0.
0.0.
0.0.
0.o*
o*o.
0.0.
o*o.
0.o*
o.o*
o.0.
o*00
4
0 .0 .
000 .
0 .0 .
0.0 .
0.0,
0.0 .
6
0.0.
o*O*
0.0.
0.0.
o*0.
0.o*
o.0.
0.0.
0.0.
0.0.
0.o*
0.0.
0.0.
00().
0.0.
e
8
0.0.
o*0.
o*0.
0.0.
0.o*
o.0.
o*0.
o*0.
0.0.
0.0.
o*o.
0.0.
0.0.
0.0.
0.0.
9
384.384.
384.384.
384.304.
384.384.
384.384.
3k34.3&4 .
384.384.
384.384.
384.384.
384.384.
3&4.3tJ4.
o.0.
0.0.
0.0.
0.o*
o.o*
0.0.
3132.3 1 3 2 .
632.216.
3132.3132.
632.216.
0.0.
313203132.
4 3 2 .2 1 6 .
060 .
0 .0.
0.0 .
3132.3132.
4 3 2 .216.
3132.3132.
4 3 2 .2 1 6 .
3132.3132.
432.216.
22 ONSITEOFFSITE
23 ONSITkoFFSITE
24 ONSITE(JFFSITE
25 ONSITEOFFSITE
26 ONSITEOFFSITE
27 ONSITEOFFSITE
2b ONSITEOFFSITE
29 ONS1 TEoFFSITE
30 ONSITE(.)FF’31 TE
576.0.
384.0.
384.
0 .
3&4 ●
O*
3 8 4 .0.
384.0 .
1 9 2 .o*
1 9 2 .0 .
1 9 2 .0 .
180.180.
120.120.
120.120.
120.120.
120.120.
120.120.
60.60.
60.6CI.
60060.
o*O*
O*o.
o*O*
0.o*
O*0.
o*o.
o*o.
0.o*
0.0.
0.0.
0 .0 .
0.0.
0..0.
0.o*
o.0.
0.0.
0.0.
0.0.
0.0 .
3132.3132.
4 3 2 .216.
000.
o*0 .
o*0.
2268.226a*
288.144*
090 .
2268.2268.
0.0 .
o*o .
289.144.
o*0.
2178.2178.
288.144.
o*0.
0 .0.
a.o.
2088.2 0 8 8 .
28a.1 4 4 .
0.0.
2088.2088.
2 8 8 .144.
0.0.
0.0.
1044.1044.
J44.7.2.
0.0.
1044.1044.
o*o.
0.o*
144.7 2 .
0.0.
1 0 4 4 .1044.
144.72.
** StEo
“ACHEO KEY OF ACTIVITIES
* * @ @9
—
TA13LE 8-17 (Attachment)11ST OF TASKS BY ACTIVITY
Activity1
2
3
4
5
6
1
8
9
10
Service Bases
Task 1 -Task 2 -Task 5 -Task 6 -Task 7 -Task 8 -Task 11 -Task 12 -Task 13 -Task 20-Task 23 -Task 24 -Task 27 -Task 28 -Task 31 -Task 33 -Task 37 -Task 301 -
ONSHORE
(Onshore Employment - which would include all .onshore administrate ion, service base operations,rig and platform serviceExploration Hell Oril IingGeophysical ExplorationSupply/Anchor Boats for RigsDevelopment Dri 11 ingSteel Jacket Installations and CommissioningConcrete Installations and ConnnissioningSingle-Leg Mooring SystemPipeline-Offshore, Gathering, Oil and GasPipeline-Offshore, Trunk, Oi 1 and GasGravel Island ConstructionSupply/Anchor Boats for PIatformSupply/Anchor Boats for Lay BargeLongshoring for PlatformLongshoring for Lay BargePlatform OperationMaintenance and Repairs for Platform and Supply BoatsLongshoring for Platform (Production)Gravel Island Construction
Hel icopter ServiceTask 4 - Helicopter for RiasTask 21 -Task 22 -Task 34 -
ConstructionService Base
Task 3 -Task 10 -
Pipe CoatingTask 15 -
Hel ico~ter Supper; for PlatformHelicopter Support for Lay Barge}Iel icopter for Platform
Shore Base Construct ionShore Base Construction
Pipe Coating
Onshore FJ@inesTask 14 - Pipeline, Onshore, Trunk, Oil and Gas
TerminalTask 16 - Marine Terminal (assumed to be oil terminal)Task 18 - Crude Oil Pump Stat ion Onshore
LF!G PlantTask 17 - LNG Plant
Concrete PI at form Construct ionTask 19 - Concrete Platform Site PreparationTask 20 - Concrete Platform Construction
Oi 1 Terminal OperationsTask 36 - Terminal and Pipeline Operations
LNG Plant OperationsTask 38 - LN~erations
OFFSHORE
Activit~11 -z
Geophysical and Geological Survey
12 ~Task 1 - Exploration Mel 1
13 Platforms——Task 6 - Development Oril lingTask 31 - OperationsTask 32 - Workover and Wel 1 Stimulation
Platform InstallationTask 7 - Steel Jacket Installation and CommissioningTask 8 - Concrete Installation and CommissioningTask 11 - Single-Leg Mooring SystemTask 20 - Gravel Island construct ionTask 301 - Gravel Island Construction
15 Offshore Pipeline ConstructionTask 12 - Pipeline Offshore, Gathering, Oil and GasTask 13- Pipeline Offshore, Trunk, Oil and Gas
16 ~ly/Anchor/Tug BoatTask 5 - Su~ply/Anchor Boats for Ri 9sTask 23- Supply/Anchor %oats for PlatformTask 24 - Supply/Anchor Boats for Lay BargeTask 25 - Tugboats for Installation and TowoutTask 26 - Tugboats for Lay Barge SpreadTask 29 - Tugboats for SLMSTask 30 - Supply Boat for SLMSTask 35- Supply Boat for SLNS
●
WEAR AFTERLEASE SALE
:34567&9
1011121314151617181920212223242526,27282930
**
e●
OhISJ TE(MAFd-FiOt4TtiSl
urr>numc
]4!2.2518.362k.5036.2212.4262.6098.6976.4384 ~4t65b .3 4 8 0 .3 3 1 2 .3852.3852.3&52.3 8 5 2 .385.203852.3&s2.3852.3852.3852.2768.274d.2658.256ti.2568.1284.1284.1284.
UN>IIUHC
2 1 6 .354 ●
4 9 2 .7 0 8 .
1154.2 4 5 4 .&~73*]820.1692.]764.1638.1 6 2 0 .1 6 2 0 .1 6 2 0 .1620.1 6 2 0 .1 6 2 0 .1 6 2 0 .1 6 2 0 .1 6 2 0 .1 6 2 0 .1620.1 3 6 8 .1 3 6 8 .1368.1 3 6 8 .
9 8 4 .732.7 3 2 .7 3 2 .
TABLE 8-18
5UMMAtiY OF t.iAt4PowER REQUIREMENTS FOK ALL I140UsTmEs
TOTAL
k62&.2b72.4116.5744.3 3 6 6 .6716.
10272.8 7 9 7 .8076.6 4 2 0 .5118.6932.5 4 7 2 .5 4 7 2 .5472.5 4 7 2 .5 4 7 2 .5 4 7 2 .5472.5 4 7 2 .5 4 7 2 .5472.4116.4116.4 0 2 6 .3 9 3 6 .3 5 5 2 .2016.2 0 1 6 .2 0 1 6 .
TOTAL INCLUDES ONSITE AND OFFSITE
ONSITE AND TOTAL **
TOTAL(HAN-FIONTHS)
urr ~llUKL
2S16.4374.6232,874a.3716s7817.
11s55.13622-12552.909b.6 7 4 4 .640a.74a8.7 4 8 8 .7 4 8 8 .7680.7488.7488.74aa.7 .488 .748t!.7 4 8 8 .5 3 5 2 .5 3 5 2 .5 1 7 2 .4 9 9 2 .4 9 9 2 .2496.2496.2496.
.-..-’-.-.,,-.,. ,- ONSHORE
2 9 6 .473.6 5 9 .95s .1337*2774.4:34.28a4 ●
2736.2M08*2682.2664.2664.2664.2664.2 6 6 4 .2 6 6 4 .2 6 6 4 .2 6 6 4 .2 6 6 4 .266k .2 6 6 4 .2 3 5 2 .2 3 5 2 .2 3 5 . 2 .2352.1584.1 2 7 2 .1 2 7 2 .1 2 7 2 .
TOTAL
2812.4 8 5 1 .6891.9 7 0 3 .5 0 5 3 .
10591.16189.1 6 5 0 6 .152aa.11904.
9 4 2 6 .9 0 7 2 .
ioi52.1 0 1 5 2 .10152.1 0 A 5 2 .10152.10152.10152.10152.10152.10152.770k.7704.7 5 2 4 .7 3 4 4 .6576.3 7 6 8 .37bae3 7 6 8 .
TOTAL MONTHLY AVIWAGE(NUMBER OF PEOPLE)
OFFStIORE ONSHORE
210.365.520.729.310.652.9 6 3 .
1136.1046.75t3.562.534.624.624.624.624.624.624.624.624,624.624.446.446*43i.416.416.206.208.208.
2 5 .40.5 5 .8 0 .
112.2 3 2 .3a7.2 4 1 .2 2 8 .2 3 4 .2 2 4 .2 2 2 .Z’22.2 2 2 *2 2 2 *2 2 2 .2 2 2 .2 2 2 *2 2 2 .2 . 2 2 .2 2 2 .222.1 9 6 .196.1 9 6 .196.1 3 2 .106.106.1 0 6 .
TOTAl.
2 3 5 .405.5 7 5 .8 0 9 .4 2 2 .a a 3 .
1350.1376.1274.9 9 2 .7a6.7 5 6 .a4b*a46 ●
a46*a46.a46*8 4 6 .846.8 4 6 .646.846.642.642.6 2 7 .612.5 4 a ,314. .314.314.
e o ●
8.6 Environmental Considerations
The low find case will presumably bear all of the impacts discussed under
exploration only scenario but impacts arising from development will be
reduced to those associated with offshore pipeliffes, drilling and construc-
tion of gravel islands, and terminal facilities at Nome.
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APPENDIX A
●
APPENDIX A
THE ECONOMICS OF FIELD DEVELOPMENT IN THE NORTON BASIN
1. Introduction
The economic analysis of the development of oi”l and gas resources in the
Norton Sound evdltiatecl three basic production systems and a variety of
physical parameters that effect the economic results.
1. Ice reinforced steel platform with a pipeline to a new shore
terminal;
2. Gravel Island in shallow water with ~ pipeline to a new shore
terminal;
3. Ice reinforced steel platform with offshore loading.
The steel reinforced platforms with a pipeline to a new shore terminal were
evaluated under the following physical parameters.
1.1 Oil
1. Initial Production rates:
2. Reservoir Target Depth:
1000, 2000, 5CO0 B/D/well;
762 meters (25[10 feet), 1525 meters (5000
feet), 2286 meters (7500 feet);
3. Water Depth: 15 meters, 30 meters, 45 meters;
4. Pipeline distance to shore: 16 to 160 kilometers (10 miles to 100
miles).
Cases were screened in 1979 dollar values with the mid-range well-head price
assumed to be $18.00. This well-head price is tied to the world price of
‘OPEC “marker” crudes laid-into the Gulf Coast of the United States as ex-
(I). All cases were price sensitivity tested withplained in Chapter 3
upper and lower oil prices equal to $25.00 and $14.50. So, too, all cases
were sensitivity tested with upper and lower limit costs equal to 150% and
75% of the mid-range values shown. Oil production was assumed to begin with
(1) The e c o n o m i c a n a l y s i s w a s c o n d u c t e d p r i o r t o t h e D e c e m b e r , 1979, OPEC
p r i c e i n c r e a s e s .
A-1
O*
*
*
●
) partial capacity in the fifth year and step up
s e v e n t h y e a r (1). A c a s e t o e x a m i n e t h e e f f e c t
a f t e r c o n s t r u c t i o n has b e g u n e v a l u a t e d d o n e - y e a r
1 . 2 Gas
to peak production in the
of a delay on the project
znd two-year delay.
1. Initial Production Rates: 15 or 25 MMCFD/well.
2. Reservoir Target Depth: 762 meters (2500 feet) and 2286 meters
(7500 feet).
3. Pipeline distance to shore: 16 kilomet[!rs to 100 kilometers (10
miles to 100 miles).
Cases were screened in 1979 dollar values with the mid-range well-head prices
assumed to be $2.60. This is based on the Natural Gas Policy Act of 1978.
Upper and lower limit prices were assumed to be $2.25 and $3.25 for sensitiv-
ity testing. Upper and lower limit costs equal to 150% and 75%.of mid-range
values were sensitivity tested.
Gas discovered in the Norton Basin will have to ~e converted into LNG for
transport to major markets. No investment in LN(i processing equipment has
been included in this analysis. The gas is assulued to be sold to the LNG
processor at the end of the pipeline. This economic screening is thus an
evaluation of offshore gas production technology under the assumption that
another $4-5 per MCF to process and ship LNG could be added to either the
mid-range well-head price or the estimated price to earn a 15% hurdle rate of
r e t u r n . Further study would be required to pin-qown with greater accuracy
the cost of processing and shipping LNG and marketing LNG in domestic west
coast or foreign markets at total costs in the range of $5-7 MCF. Theresults of this study do not imply that gas could be marketed at an economic
p r i c e . R a t h e r t h i s s t u d y only c o n s i d e r s w h e t h e r g a s i s e c o n o m i c a l d e v e l o p -
able given allowable well-head prices. This marketability question is a
larger issue, which is addressed in Appensix F.
(2) From decision to develop; about two years from assumed discovery date.
A-2
●
II.
11.1
Analytical Results
Minimum Field Size to Justify Development
11.1.1 Oil
11.1.1.1 Effect of Reservoir Target Depth on Oil Field
Development Economics
The amount of
lifetime of a
deviation that
oil that can be recovered from a single platform over the
field is related to the depth of the reservoir, the angle of
the wells can achieve and the recoverable reserves per acre or
*
acre-foot. Recoverable reserves
reservoir conditions including
connate water percentage, etc.
per acre-foot is dependent on a host of
porosity, permeability, drive mechanism,
8
A s s u m i n g 5 0 ° angle of deviation a single platform
on Table A-1 as a function of target depth under
oil field is irregularly shaped the platform could
can reach the areas shown
ideal conditions. If the
reach fewer acres.
Recoverable reserves per acre-foot in the range of 200-600 barrels is not
unreasonable. One thousand barrels per acre-foot is possible under extremely
ideal conditions, but unlikely in Norton Basin. An acre-foot filled only
with oil would contain approximately 7640 barr~~ls. One thousand barrel
recovery would imply 13% recovery. But oil does not occur with nothing else
in the same space. Oil occurs between sandstone particles and among other
mineral deposits and usually with some water mixed in. If half of the space
were filled with oil -- 3,820 barrels -- 1000 barrel recovery would imply 26%
recovery. In reality, less than half the space is filled with oil under most
conditions and primary recovery ranges from 25-35% of reserves.
The assumption that recoverable reserves per acre range from 20,000 to 60,000
barrels implies an assumption about reservoir thickness given our 200-600
barrel per acre-foot assumption. At the extreme values, 32 meter (100 foot)
thickness is implied. Although highly prolific fields with reservoirs much
th
in
●
e
c k e r t h a n 3 2 m e t e r s ( 1 0 0 f e e t ) e x i s t , t h e g r e a t e r nurriber o f f i e l d s h a v e ,*
f a c t , r e s e r v o i r s e c t i o n s l e s s t h a n 1 0 0 f e e t t h i c k . T a b l e A - 1 s h o w s*
A-3 ●
TABLE A-1
MAXIMUM ULTIMATE RECOVERABLE RESERVESFROM A SINGLE PLATFORM—— ..—
Area ofcoverage
from a singleReservoir platformtarget with 50” welldepth deviation
Meters (Feet) Acres
762 ~~,;~~; 601525 19202286 (7 ;500) 4466
Maximum
r e c o v e r a b l e s
r e s e r v e sa t
2 0 0 0 0 0 6 0 0 0 0 0
BBLS/Acre BBLS/Acre
12.8 38.438.4 115.289.3 268.0
Maximumnumber of wells
that can be drilledfrom a platformwith well-spacing
of80 Acres/well 160 Acres/well
8 424 1256 28
Source: Dames & Mooe Calculation
A-4
maximum recoverable reserves that can be reached from a single platform
associated with the reservoir target depths that fit the geology of the
Norton Basin. T h e g e o l o g y o f t h e b a s i n s u g g e s t s t h a t s h a l l o w t a r g e t s m a y b e
e n c o u n t e r e d . lnterpretaticn o f T a b l e A - 1 s h o w s t h a t f o r s h a l l o w r e s e r v o i r s :
1. Platforms can only house 8 wells given standard industry spat
of 80 acres;
2. A single platform can recover orIly 38.4 million barrels over ~
lifetime.
ng
ts
Large reservoirs at shallow depths would thus require multiple platforms.
Table A-2 shows the results of the economic analysis of reservoir target
depths. The shallow reservoir case -- 762 meters (2500 feet) -- is config-
ured assuming the most optimistic values for water depth - 15 meters (50
feet); i n i t i a l p r o d u c t i o n r a t e -- 5000 B/D; and pipeline distance to shore --
16 kilometers (10 miles).
C o n s t r u c t i n g t h i s c a s e w i t h t h r e e p l a t f o r m s sha:-ing a p i p e l i n e t o a s h o r e
terminal allows for economies in the pipeline cost and thus, improves the
e~onomics over a single platform field developntent. Three platforms can
recover a 115.2 ~ barrel field. Column 9 shows that even under these opti-
mistic conditions the shallow reservoir is able to eawrn a return on invest-
ment of only 4.8%. Column 10 shows that the well-head value for a barrel of
oil would have to be $26.25 to earn 15%.
The production systems for the 1,525 (5,000 feet) and 2,286 (7,500 feet)
meter reservoir are exactly comparable. Twenty-four producing wells are the
maximum that can be drillied from the platform with a 1,525 meter (5,000
feet) reservoir depth.
(7,500 feet) reservoir.
Costs rapidly increasereach deeper targets.
Forty is the upper limit assumed for the 2,286 meter
as platform size increases to house more wells to
Wells to the deeper target are more costly. The
A-5●
—.
TABLE A-2
2.— ‘J
EFFE~ OF RESERVOIR TARGET DEPTH ON OIL FIELD DEVELOP?IENT ECONOMICS
& ~ Q ~
Pipelinedistance Numberto shore of
ReservoirInitial
terminal Number producingtarget Water (offshore/
productionof wells per
depth depthrate
on-sliore) ~latforme platform per well
(Meters) (Meters) (Km) (!@D)
762 15 16-3 3 a 5,000
1525 45 3 2 - 3 1 2 4 2 , 0 0 0
2286 45 32-3 1 40 2,000
NE - Not Economic
Source: Dames k Moore Calculation
r (1) Maximum recoverable reserves over the life of the project are defined bym the number of producing wells that can reach a reservoir target and the
initial production rate of the reservoir. Standard reservoir engineeringpractices to achieve MER are implied.
tttnimumfieldsize
Mid-range to earn
investment 10Z 15%
($i) (m)
$890.6 NE NE
$443.2 75 NE
$&33.5 160 240
Return onInvestmentfor maximum Minimum
required‘;::~:le(l) price (2)
(m) (%) ($)
115.2 4.8 26.2S
115.2 12.u 21.00
268 1 5 . 1 1 7 . 9 0
(2) The minimum required price Co earn 15% after tax over the production lifeof maximum recoverable reserves.
platform to house 40 wells is larger and has more equipment to handle the
80,000 B/0 peak rate compared to 48000 for 24 wells. The larger peak
throughput entails a larger share of shore terminal capacity and a propor-
tionately larger share of terminal cost. In total, Table A-2 shows that the
production system for the 2286 meter reservoir is over 80% more costly than
the 1525 meter reservoir. However, the rate of return associated with the
maximum recoverable reserves on the more costly system is 15.1% compared
to 12.8% for the 24 well system. The ability to produce more oil (total
reserves) more quickly (peak production rate) through the larger platform
overshadows the increased cost. Over the lifetime of the field the deeper
target allows maxiumum ultimate recovery of 6.7 I barrels per well compared
to 4.8M barrels per well for the 1525 meter target.
11.1.1.2 Effects of Water Depth on Oil Field Development’
Economics
Table A-3 shows the results of the analysis to examine the sensitivity of
water depth on the economics of field development. In this case, the produc-
tion profile is the same for each water depth. The maximum ultimate recovery
is 6.7 ~ barrels per well over the 18-year production life of the field.
Thus, changes in rate of return are wholly associated with changes in plat-
form investment cost due to increased water depth.
Clearly, in the Norton Basin, water depth is not critical. Minimum field
size to earn 15% varies between 200-400 M barrels as water depth increases
from 15 to 45 meters (50 to 150 feet). The rate of return earned from pro-
ducing 268 ~ barrels, the maximum single platform recoverable reserves, de-
clines from 17.2% to 15.1% as water depth increases. The minimum’ price re-
quired to earn 15% increases from $16.25 to $17.90 as water depth increases.
11.1.1:3.
Table A-4 shows the
economics. Initial
9
9The Effect of Initial Well Production Rates on
Oil Field Development Economics
effect of initial well productivity on field development
well production rates affects the selection of platform●o
TARLE A-3
Pipelinedistanceto shore
Reservoir ierminalWater tsrget (offshore/depth depth on-shore)
(Meters) ( M e t e r s ) (Km)
15 2286 32-3
30 2286 32-3
45 2286 32-3
EFFECT O? WATER DWTN ON OIL FIELD DEVELOPMENT ECONOfICS
& ~ q ~
Numberof
Number producingof wells per
platforms ~lacform
1 40
1 60
1 40
Source: Dames & Moore Calculation
~ (1) See Table A-2Cu
(2) See Table A-2
Initialproduction
rate Mid-rangeper well investment
(M-OD)($E)
2,000 $704.5
2,000 $110.6
2,000 $803.5
Ninimumfieldsize
Co earn10%1 5 %
(m)
130 200
150 225
160 240
Retura oninvet3tmentfor maximum Minimumrecoverable~e$eme, (1) ‘e;;:::d (j)
dial (%) ($ )
268 1 7 . 2 1 6 . 2 5
268 1 5 . 8 1 7 . 2 S
268 15.1 17.90
TAME A - 4
EFFECT OF INTIAL WELL PRODUCTIVITY ON FIELD DEVELOPMENT ECONWICS
Pipeline
Initialdistance
product ionto shore
rate Hater Reservoir terminaltarget (offshore/
per well depthdeoch
(MBD)on-shore) ~~)
( M e t e r s ) (llecers) (Km)
1000 15 1,52> 16 -3
1000 15 2,286 16 -3
2000 15 2,286 16 -“3
5000 15 2, 2S6 16 -3
Number
ofplatforms
-1 1lo Pipeline to shore is assumed to be half shared with another producing field.
2 See Table A-2 (1)
3 See Table A-2 (2)
Source: Dames & Moore Calculations
*
6—
Mmberof
productngwells perplatform
24
60
40
20
~
Mid-rangeinvestment
($ti)
$330.0
$505.0
$759.1
$595.5
MinhllrJfieldsize
to earnlox 15%
(m))
N% NE
150 NE
140 215
(loo -190
10—
Recuro oninvestmentfor maximum Minimum
‘:~::le(2) req;:::d(3)
(FiLo (%) ($)
115.2 9.2 25.00
268 1 3 . 2 20.30
268 15.2 16.75
268 20.0 14.40
1 equipment, the number of wells to produce a field, the size of pipeline, and
share of shore terminal costs. These affect costs.
The first case shows that with a reservoir target of 1525 (5,000 feet), 24
wells producing at 1000 B/D cannot recover the oil quickly enough to earn a
minimum 10% hurdle rate of return. Twenty-five dollars a barrel of oil would
be required to earn 15%.
The next two cases compare the effects of 1000 B/D and 2000 B/D initial
production rates on the economics of producing a deep reservoir. At 1000
B/D, 40 wells are unable to recover the oil fast enough to earn 15%. Thus,
in the Norton Sound where geological conditions suggest 1000 B/D initial
production rates might be reasonably expected, platforms will need to house
more than 40 producing wells to earn minimum hurdle rates, or oil will have
to be priced above $20.00 a barrel.
Investment costs increase 50% when
B/D. Platform deck load and the
initial production rates double to 2000
platform’s assumed share of terminal
throughput and cost increase as initial well productivities increase. Theincrease in revenue is due to faster oil recovery which more than offsets the
increase in cost for the maximum recoverable resources.
The rate of return earned from producing maximum recoverable reserves with
the larger investment associated with 2000 B/D initial production is 16.2%
compared to 13.2% for the 1000 B/D production system. The minimum field size
to earn 15% is 215 million barrels.
If initial production rates were 5000 B/D, fewer wells would be required to
produce the reservoir. Thus, the platform would be smaller. Investment is
20% lower than the 2000 B/D case. The rate of return for maximum recoverable
reserves is 20.0%. Oil priced at $14.40 per barrel would earn 15%.
No other case screened in the entire analysis earned 20% on investment. The
magnitude of the investment costs together with high operating costs in the
Norton Sound suggest that ideal reservoir conditions will be required to earnt15-20% hurdle rates.
A-I(?
11.1.1.4 The Effect of Pipeline Distance to Shore on
Oil Field Development Economics
Table A-5 shows the effect of pipeline costs on oil field development
economics. The production profile is identical in each case. Only the
investment flows change as pipeline distances increase. The investment costs
of these cases assume all pipeline costs are supported by a single platform.
In reality there may be opportunities to share a I.runkline among several
producing fields.
Column 8 shows that the minimum field size to earn 15% increases from 215 ~
to 250~ barrels as pipeline distance to shore increases from 8 to 48 kilo-
meters (5 to 30 miles). Beyond 48 kilometers (30 miles), the investment cost
of an unshared pieline is so large
earn 15%.
Figure A-1 shows the relationship
shore and the ratge of return. At
that this production system is unable to
between offshore pipeline distances to
160 kilometers (100 miles), the maximum
recoverable reserves for a single platform will e?rn 12%. G
If p i p e l i n e c o s t s w e r e o n e - h a l f t o o n e - t h i r d sha~-ed w i t h o t h e r f i e l d o p e r a -
tors, pipeline distances from shore that will carp a 15% hurdle rate approx-
imately double and triple to 96 to 145 kilometers (60 to 90 miles).
The 40-kilometer (30-mile) limit to earn a 15% ourdle rate for a pipeline
whose cost can not be shared with other field operators implies that for
fielcls discovered beyond this limit offshore loading will be required.
Table
field
basic
24 ki
11. 1.1.5 Effect of Delay on Oil Field Development Economics
A-6 shows the impact of a potential delay in production start up on oil
development economics. One year and two year delays are analyzed. The
production system is taken from Table A-3: a deep reservoir field with
lometers (15 miles) of offshore pipeline to a shore terminal. This
●
TABLE A-5
Pipelinedistanceto shoreterminal
f::::!::’(l)
(Km)
161( l o o )
2—
Waterdepth
(&tera)
45
45
45
.45
65
EFFECT OF PIPE1.INE DISTANCE TO SNORE ON ~l?lJl DEVELOP?EXIT ECONOPICS
Numberof Initial
producing product ionwells per rateplatform per well
(MBD)
Numbero f
platforms
Reservoirtargatdepth
(Meters)
2266 1 40
2286 1 40
2286 1 40
2286 1 40
2286 1 40
2,000
2,000
2,000
2,000
2,000
1All pipeline investment is assumed to be unshared.
2 See Table A-2 (1)
3 See Table A-2 (2) Source: Damee & Moore Calculations
10—
Minimum Return onfield investmentsize for maximum Minimum
Mid-range to earnInvestment 10% 15%
r::~;:wz) r’q;&(3)
($ii)
$759.1
$788.4
$803.5
$827.2
$1,022.6
(FIN) (m) (%)
140 215 268 16.5
150 230 268 15.5
160 240 268 15.1
165 250 268 15.0
w200 NE 268 12.0
($)
16.75
17.40
17.80
17.90
21.60
e
!-.‘<a 13
12
11I I I I
20 40 60 8 0 100 (MILES)
1 I I I I ! I I —-io 20 40 60 80 100 120 140 160 (KILOMETERS)
PIPELINE DISTANCE
Figure A-1
EFFECT OF OFFSHORE P! PEL!NE DISTANCE ON RATE OF RETURN(C)ilflel~: 2G8 1%8 R~ser’ve~, 2,000 8iD W~llS,
2,2E36 m Reservoir, A5 rn water De@~]
●
TABLE A-6
Reservoirtargetdepth
( M e t e r s )
BASECASE :
2286
ONE-Y&AR DELAY
No change
h TWO-YEAR DELAY.,h NO change
EFFECT OF DELAY ON OIL !UELD DEVELOPMENT ECONOMICS
Pipelinedistance Numberto shore of Initialterminal Nunber p r o d u c i n g
Water ( o f f s h o r e /p r o d u c t i o n
o f wells per ratedepth on-shcre) platforms platform per well
(Metere) (Km) (MBD)
’45 1 6 - 3 1 40 2,000
Netpresentvalue of
caah flowsat 15%
Mid-range discountinvestment rate
($ii) ($ii)
$ 7 8 8 . 2 10.8
( 53.3)
( 1 6 7 . 7 )
Return oninvestmentfor maximum tlinimumrecoverable (l) req:I~~2)reserves P
(FIB) (%) ($)
268 1 5 . 5 1 7 . 4 0
268 1 3 . 5 20.50
268 1 0 . 0 @27.00
Source: Dames 6 Moore Calculation
(1) See Table A-2
(2) See Table A-2
production system cost $788.4 M and required a 230 M barrel field to earn
15%. Investment flows occured over ii six year period. Oil production
started in the fifth year and stepped up to peak in the seventh year.
Delays may
very narrow
up and put
occur at any time and for a variety of reasons. Missing the
annual “weather window” during which the platform may be towed
on target is one potential source of delay. Permit delay is
another potential source. When the delay occurs relative to how much in-
vestment has been made is critical to the impact of delay on the economics.
The one-year delay is a “worst” case. The investment flow are identical to
the base case, but production starts one year later, in the sixth year
instead of the fifth. The two-year delay represents a two-year “stretch out”
of the project beginning in the third year. ‘Investment flows occur for eight
years. Production begins in the seventh year and peaks in the ninth. The
stretch out of the investment flows moderates the impact of the two-year
delay on the field development economics.
Columns 8, 9 and 10 of Table A-6 show how much a delay can harm the outcome
of a development project in the Norton Sound. A one year “worst case” delay
can turn a $20.8 million winner into a $53.3 million loser. (The new present
value of revenue and cost cash flows are exactly equ~l when a project just
earns its hurdle discount rate, 15% in this case. A positive net present
value implies the project is able to earn more than the hurdle rate. The
base case has a 10.8 million positive net present value and earns 15.5%.)
A two year delay in a project would severely reduce the
project. The second year of delay, even with investment
makes the net present value of cash flows more than $100
year delay. The best this project could earn would be
oil would have to be priced in the range of $Z7.00.
profitability of the
flows stretched out,
~ worse than the one
10.0%. To earn 15%,
11.1.1.6 The Effects of Other Production Systems on
Oil Field Development Economics
Two Platforms
Table A-7 shows
development and
the analysis of two-platform development, gravel island
offshore loading. The two platform case compares to the
A-15
9
*
o
●
Reservoirtarget Waterd$p~h der.th
(Meters) ( M e t e r s )
TWO PLATFORMS
2286 30
GRAVEL I SLAIID
2286 30~
~ OFFSHORE LOADING
2286 15
TA8LE A-7
EFFEXX OF OTHER PRODUCTION SYSTEMS ON OIL FIELD DEVELOPMENT ECONOtlICS
~
Pipelinedistanceto shoreterminal
(offshore/on-shore)
(Km)
3 2 - 3
3 2 - 3
k
Numberof
platforms
2
1
1
>
Numberof
producingwells perplatform
40
40
40
Source: Dames 6 Moore Calculations
(1) See Table A-2
(2) See Table A-2
Initialproduction
rate Hid-rangeper well investment
(M8D) ($fi)
2,000 $1,392.8
2,000 $ 687.5
2,000 s 687.9
Minimum Return onfield inveatmeatsize for maximum Minimum
t o e a r n recwerable10% 15% reserws (1) ~~~~d(2)
(ml) (iiD). (z) ($)”
2 5 0 4 2 5 536 16.0 $17.25
125 2 0 0 6 8 18.0 $15.25
125 190 68 18.0 $15.25
$770.6 M single platform development case in 32 meter (100 feet) water depth
shown on Table A-3. If a reservoir is
platform, the incremental investment is
related to pipeline and terminal costs
development for very large reservoirs.
large enough to support the second$622.2 ~. There are some economies
associated with two platform field
The minimum field that will support two platforms and earn 15% is 425 ~
barrels. The maximum recoverable reserves for two platforms -- 536 M barrels
-- will earn 16%.
Gravel Islands
Gravel islands appear to be less costly and consequently more economic than
the steel platform
to the same $770.6
rate of return for
that gravel is lands
development option. The gravel island case compares
~ steel platform alternative op Table A-3. The higher
the gravel island -- 18.0% compared to 15.8% -- suggests
may be preferred technology in shallow water.
Offshore Loading
For the isolated platform too far from shore for a pipeline, offshore loading
w~th storage to allow full-protection is extreml!ly economic. The minimum
field size is less than 200 ~ barrels. Such ~1 system would involve the
caisson-retained production/storage/loading islan~ concept proposed by Dome
Petroleum for the Beaufort Sea. The estimated costs for such a system are,
however, highly speculative. Offshore loading without storage and limited to
65% production has been shown in our analysis of the Gulf of Alaska to be
mostly uneconomic.
11.1.2 Non-Associated Gas
Table A-8 shows the results of the economic analysis of the development of
non-associated gas. Three cases were analyzed to consider the effects of
various reservoir characteristics on the development of natural gas:
●
a
●
A-17
— —
TADLS A-8
EFFECT OF RESERVOIR CONDITIONS ON GAS FIELD DEVELOPMENT ECONOMICS
Reservoir NumberHid-range Water tar~et ofinvestment depth depth Dlatforme
($M) (Meters) (Meters)
Numberof
producingveils perplatform
Initialproduction
rateper well
(MMCFD)
Pipelinediataoce Maiml@a Return onto shore field investmentterminal sire for maximum Minilmm
(offshore/ to earn requiredon-shore) 10% 15% ‘::::le(l) price (2)
(Km) (BCF) (B12F) (%) ($)
,GAs CASE IReservoir Target Depth(A) Shallow Reservoir $i21. o 15 760 1(B) Deep Reservoir $269.9 30 2286 1
GAS CASE IIInitial Production Rates(C) Fast Recovery $252.3 30 2286 1
Moderate Rec~very (See B)
GAS CASE 111
Pipeline Distances16 Kilometers (see B)
(D) 32 Kilometers $315.3 30 2286 1(E) 29 Kilometers $471.6 30 2286 1
416
1616
1515
25
1515
16-3 NE NE” 192 0 3.2516-3 750 750 1344 20 2.00
16-3 <750 <750 1344 24.3 1.35
32-3 4750 -1000 1344 18.0 $2.15129-3 .-”1000 NE 1344 13.2 $2.90
S o u r c e : Dames & Moore Calculations
(1) See Table A-2I II
(2) See Table A-2
Case I : Reservoir Target Depth
Case 11: Initial Production Rates
Case III: Pipeline Distances to Shore
Water depth effects were not examined because the oil reservoir analysis
showed that in the shallow waters of Norton Sound water depth is not a
factor.
11.1.2.1 Effects of Reservoir Target Depth on Gas Field
Development Economics
Case I shows that shallow reservoir gas fields with standard industry
well spacing of 160 acres/well allow a maximum ultimate recovery of only
192 BCF of reserves (assuming recoverable reserves per acre of 300,000
MCF) . This is insufficient to earn 10% return on investment. Over the
lifetime of the field each of the four wells on the shallow reservoir is
able to recover a maximum of only 48 BCF. The deeper target allows 16
wells with spacing of 280 acres to recover 84 BCF each over the production
life of the field. A shallow reservoir field woJld need to be priced above
$3.25 MCF to earn 15% return on investment.
Case I shows that the much “larger ultimate recovery makes a large difference.
The deep reservoir gas field would earn 20% with a maximum ultimate recover-
able reserves of 1.344TCF.
11.1.2.2. Effect of Initial Production Rates on Gas
Field Development Economics
Faster recovery
that the minimum
improves the economics of development. Gas Case II shows
required price to earn 15% producing the deep reservoir with
the maximum recoverable reserves of 1.334 TCF drops from $2.00 MCF with 15
MPICFD/well initial production rate to $1.35 with 25 MMCFD/well. Return on
investment with $2.60’we?l-head price rises from 20.0% to 24.3%. Standard
reservoir engineering would allow fewer wells at the faster recovery rate.
o●
●
☛
●
●
●
●A-19
11.1.2.3 Effect of Offshore Pipeline Distcince to Shore
on Gas Field Development Economics
Gas Case III shows that return on investment for producing the deep reservoir
of 1.344 TCF declines as pipeline distance and pipeline investment increase.
Figure A-2 shows that a field ?ocated to require a pipeline longer than 96
kilometers (60 miles) shared with another field is unable to earn 15%. At
129 kilometers (80 miles) gas would have to be pi-iced at $2.90 MCF to earn
15%.
11.2 Minimum Required Price to Justify Field Development
Given the estimated costs of various oil and gas production systems identi-
fied in this report, the minimum price to justify development (the minimum
price to earn 15% return on investment) has been calculated using the model(1) Tables A-2 through A-8 showed the minimum pricefor various field sizes.
to earn 15 percent for the maximum reservoir size that could be reached
and recovered by the production system on each ta’>le. Different production
systems with different investment costs yield different minimum prices for
development. Furthermore, the minimum required price is sensitive to water
depth, reservoir target depth and initial well production rate as well as the
assumed value of money.
In the following sections the minimum required pr:ce as a function of field
size is identified with selected reservoir characteristics.
(1) In this analysis we have provided solutions based upon a 10 to 15% rangebut emphasize 15% in discussions because we believe that is closer to indus-try practice than 10%.
A-20
e●
.
I I I I I I I I Io 10 20 30 40 50 60 7CI 80 90 1 0 0 (MiLES)1 I I I I I I I Io 20 40 60 80 100 120 140 160 (KILOMETERS) ●
PIPELINE DISTANCE
o
EFFEC7’ OF OFFSt-iOF?E FiPEl=~?4E DISTANCE ON RATE OF’ FIETURN(@is Field: 1,344 ‘TCF WWWWS, 15 MMCFD Wells,
2,28$ m Reservoir, 16 Weli Platform)
eA-21
11.2.1 Oil
Figure A-3 shows the minimum required price to ~evelop a known oil field
with a single platform with a 2286 meter reservoir target and 2000 E1/D
initial well production rate. Two production systems are shown: (1) off-
shore loading with storage capability, and (2) pipelining to shore, a dis-
tance of 32 kilometers (20 miles). The offshore loading system is less
cost?y ($688 million versus $803.5 mid-range investment cost) than the
pieline system. while the offshore loaded platform is in 15 meters (5O
feet) of water and the pipeline platform in 45 meters (150 feet) of water,
most of the cost difference is in the difference in pipeline and terminal
investment compared with offshore loading technolo{ly. For a field within 32
kilometers (20 miles) of shore, these two production technologies at the
different water depths can be said to bound the upper and lower limit mini-
mum required price. Fields further from shore with a pipeline to a shore
terminal would require higher prices.
IFigure A-3 shows that the minimum required price to earn 15% is relatively
high. For a 100 million barrel field the price is above $26.00 with offshore
loading; above $36.00 with the pipeline to shore. The minimum required
price drops below $20.00 with the offshore loading system at 150 million
barrels; with the pipeline system more than 20~1 million barrels before
the minimum price is under $20.00. At 250 million barrels, the minimum price
is $15.25 and $18.00 for the twQ systems.
The minimum required price declines little for field larger than 250 million
barrels. Barrels recovered beyond 20 years in the future add little to the
economic payoff and have little impact on minimum price calculations.
11.2.2 Non-Associated Gas
Figure A-4 shows the minimum required price for developing a known gas field
with a signle steel platform housing 16 wells. Initial productivity is
assumed to be 15 MMCFD. The platform is assumed to be 16 kilometers (10
)
A-22
I I I I I5 0 100 1 5 0 2 0 0 2 5 0 3 0 0
●
MILL1ONS OF BARRELS RECOVERABLE RESERVES
Figure A-3
MINIMUM PRICE TO JUSTIFY DEVELOPMENT’ OF AN OIL FIELD:Offshore Loading Compared with Pipeline to Shore(2,286m Reservoir, 2,000 i3/D Wells, Single Platform)
A-23 9
9
0
~~ I
.
I I I I5 0 5 0 0 ? 6 0 1 0 0 0 1 2 5 0 1 5 0 0
RECOVERABLE RESERVES, BILLION CU~lC FEET
Figure A-4
MINIMUM PRICE TO JUSTIFY DEVELOPMENT OF A GAS FIELD(Single Steel Platform with 16 km Pipeiine to Shore,
2,286 m Reservoir, 15 MMCFD/Wells)
A-24
miles) from shore. The minimum price is sensitive to pipe”
shore as previously shown with as Case III on Table A-8.
The minimum price to justify development at 15% drops from
ine distance to
$2.75 tYICF for a
500 BCF field to $1.95 MCF for 1500 BCF of recoverable reserves.
11.3 Distribution of Oil Clevelopment Costs between Offshore
Production, Pipeline Transport and Shore Terminal
Offshore pipelines will be extremely expensive in the Norton Sound. Initial
mobilization with the narrow “weather window” and installation under harsh
environmental conditions will be difficult at best.
Table A-9
decreases
kilometer
shows that the share of costs arising from the offshore platform
from 70% with a 16 kilometer (10 mile) pipeline to 49% with a 161
(100 mile) pipeline.
Figure A-1 previously showed that a pipeline longer. 48 kilometers (30 miles)
that could not be shared with another field operator added such an investment
burden that the investment could not earn a minimum 15% hurdle rate -- given
the assumptions of the analysis.
11.4 The Effect of the Uncertainty of Estimated Costs and Prices
on Field Development Economics
11.4.1 Sensitivity Analysis for Single Steel Platform Oil
Field Development
●
*
*
Table A-3 previously identified a 240 million barrel field as sufficient to
earn a 15% hurdle rate of return for a single steel platform with a 32
kilometer (20 mile) pipeline to shore and deep reservoir to allow 40 produc-=
ing wells. Table A-10 estimates the range of uncertainty of the after tax
rate of return implicit in the range of costs employed in the analysis.
A-25 ●
TABLE A-9
DISTRIBUTION OF OIL DEVELOPMENT COSTS BIWWEN OFFSHOREP R O D U C T I O N , PIPELINE TWSPORT AND TERX1l?AL (1)
($Million)
Pipeline .Jistance to Shore16 Km 48 Km 161 Km
P l a t f o r m F a b r i c a t i o n
& I n s t a l l a t i o nP l a t f o r m E q u i p m e n t
& WLscellaneous
W e l l s ( 4 5 )
Sub T o t a l : P l a t f o r m
Share of ShoreTerminal (26%)Pipeline- Onshore (3Km)- Offshore
Miscellaneous DesignEngineering
ITotal M i d - r a n g e I n v e s t m e n t
Percentage Distribution:% Platform% Terminal & Pipeline
Source: Dames & Moore Calculations
160.0 160.0 160.0
210.0 210.0 210.0180.0 180.0 180.0
550.0 550.0 550.0
153.6 153.6 153.6
6.0 6.0 6.053.2 106.5 355.0
21.3 26.6 51.5
$784.2 $842.7 $1116.1
70.0 65.0 49.030.0 35.0 51.0
{1) Single steel platform with 40 producing wells,in 45 meters water depth with 2286 meter reservoirtarget. Initial well production rate - 2000 B/D.The shore terminal is assumed to transship 300MBD. Cost is shared in proportion to peak productionrate.
A-26
TABLE A-10
SENSITIVITY ANALYSIS FOR Al?TER TAX IQ4TE OF RETURNAS A FUNCTION OF UPPER & LOWER LIM?T OIL DEVELOPMENT COSTS (1)
Lower Mid-range Uppercost cost cost =
Tangible I n v e s t m e n t 17.3 15.0 11.6 5.7
Intangible Investment 1 6 . 5 15.0 12.4 4.1
Operating Costs 15.5 15.0 13.9 1.6
General & Administrativecosts
●15.3 15.0 14.5 008
Source: Dames & Moore Calculation
(1) Single steel platform witih 40 producing wellsin 45 meter water depth, with 2286 meter reservoirtarget. 2000 E/D ifitial production rate. 32Km pipeline. Recoverable reserves - 240 millionbarrels. Mid-range investment: $803.5 million
●
●
.A-27
●
) Fifteen percent rate
range cost estimates.
were estimated at 75%
of return is the expected rate of return for the mid-
Upper and lower limit tangible and intangible costs
and 150% of mid-range costs.
Mid-range operating costs were estimated at $32 million annually with upper
and lower limit of $24 and $48 million. Mid-range administrative costs were
estimated at $8 million with upper and lower limits of $6 and $12 million.
Administrative costs start when development begins; operating costs start
when production begins.
The upper and lower limit rate of returns for each variable on Table A-10
assumes all the other variables at their mid-ranga values. The variables are
listed in the order of their effect on the range of variability of the rate
of return. Clearly, if tangible or intangible investment are closer to high
cost estimate than to mid-range, development of this 240 million barrel field
could earn substantially less than 15%. The range of uncertainty in operat-
ing and administrative costs has much less impact on the success of the
1 development project. At their mid-range values, the sum of operating and
administrative costs is equal to $1.42 per barrel at peak production rate and$2.37 per average barrel over the 1 ife of the field. Per barrel operating
costs increase as field production declines.
11.4.2 Monte Carlo Results for Selected Production Scenarios
11.4.2.1 Range of Values for After Tax Return on Investment
Previous sections have reported results based on the mid-range values for
prices and costs. Repeatedly, however, this report has emphasized that costs
for production technology that will be employed in the mid-1980’s can only be
estimated in 1979 dollars within a range of values. In this section, Monte
Carlo distributions for the after-tax return on investment for selected
production scenarios are reported to emphasize the uncertainty built into
this economic analysis of field development in the Norton Sound.
Just as there is a range of values estimated for prices and costs, there is a
range of values for the profitability criteria calculated by the model. A
Monte Carlo solution to the model is a way to estimate the range of outcomes
by repeatedly solving the model with values selected at random in each
solution pass for each of the variables whose values are entered as a range.
With a few hundred solution passes, the Monte Carlo distribution reveals a
probabilistic estimation of the worst outcome, best outcome and intermediate
results.
11.4.2.2 Oil Platforms
Table A-n and Figure A-5 show the Monte Carlo results for the distribution
of return on investment for an oil development scenario that would be plau-
sible in most places of the world except Norton Sound. The field is assumed
to be a 125 million barrel reservoir. A single 40 producing well oil plat-
form with an unshared 32 kilometer (20 mile) pipeline to shore has an expect-
ed rate of return of only 5.8% with this large-by-any conventional standards
reservoir. Table A-2 previously showed that a 240 million barrel reservoir
was required, after-tax return on investment could range from 7% to 14.2%.
There is a 93.5% change of earning less than 9.9%. There is, therefore,
little change of earning even a 10% hurdle rate.
Figure A-5 shows the cumulative distribution that graphically displays these
results.
11.4.2.3 Gas Platforms
Table A-12 shows the Monte Carlo distribution for the rate of return for a
gas platform also connected to shore by a 32 kilometer (20 mile) pipeline.
Recoverable reserves are assumed to be 1.3 TCF. Table A-12 and Figure A-6
show:
●
*
c There is 2.5 percent chance of earning less than 13.5 per-
cent;●
9
A-29
—
TABLE A-11
1>
IAJ3
SINGLE OIL PLATFORM WITH 32Km PIPELINE TO SHORE125 MllLT.ON BARREL FIELD, 45M. WATER DEPTH, 2286 M. RESERVOIR TARGET
INITIAL PRODUCTION RATE: 2000 B/D
MID-RANGE INVESTMENT: $803.5 MILLION
,
Source: Dames & Moore Calculation
*
J
3
3
iII+-a17IItI:
:I1
iI
a x“
●
●
k-
SKNGLE GAS PLATFORM WITH 32 Km PIPELINE TO SHORE30 M. WATER DEPTH, 2286 M. RESERVOIR TARGET
INITIAL PRODUCTION RATE : 15 MMCF’D
1.3 TCF FIELD MID-RANGE INVESTMENT: $315.3 MILLION
Rt. >UL [ rnuti. w M lok ‘VALUL I-L3> ThAN HcSULT
-------- ------- -------.- -.--..---
4
0
I
iIIII*
iItIIII
i11tItt
:
i-oit
iI
I
itI11It+-atot-mIIItiIIIIIItI11iI+-. >I 1?:-
II
u ●Llzom
A-33
9 There is 14.5 percent chance of earning less than 15.0 percent;
o There is 100 percent chance of earning less than 23.0 percent;
o The expected value for rate of return is 17.0 percent.
While these are very favorable economic results, the 23 percent upper limit
implies that a much larger gas field than 1.3 TCF -- which is very large --
must be discovered to produce a bonanza payoff.
APPENDIX B
9e
APPENDIX B
PETROLEUM DEVELOPMENT COSTS AND FIELD DEVELOPMENT SCHEDULES
1. Data Rase
This appendix presents the field development and operating cost estimates
used in the economic analysis. Exploration costs are not included in the
economic analysis and are, therefore, not discussed here (see discussion
in Chapter 3.0).”
Predictions on the costs of petroleum development in frontier areas such
as Norton Basin (where no exploration has yet occurred) can be risky or
even spurious. Such predictions rely on extrapolation of costs from
known producing areas suitably modified for local geographic, economic,
and environmental conditions. Further, cost predictions require identifi-
cation of probable technologies to develop, produce, and transport OCS
oil and gas. For the Norton Basin, there is very little or no cost exper-
ience from comparable operating environments where petroleum development
has taken place to provide a firm data base for economic analysis.
In the course of studies on the Gulf of Alaska (Dames & Moore, 1979a and b)
and Lower Cook Inlet (Dames & Moore, 1979c), a considerable data base on
petroleum facility costs for offshore areas was obtained which provided
the starting point for this study. That data was based on published
literature, interviews with oil companies, construction companies, and
government agencies involved in OCS related research. Petroleum develop-ment cost data is either direct cost experience of projects in current
producing areas such as the Gulf of Mexico and North Sea, or projections
based upon experience elsewhere modified for the technical and environ-
mental constraints of the frontier area. For sub-arctic and arctic
areas, facility cost projections may involve estimates for new technol-
ogies, construction techniques, etc. that have no base of previous
experience.
In addition to reviewing estimated costs from current producing areas,
and projections for Cook Inlet, data was obtained on exploration cost
experience in the Canadian Beaufort Sea and projl~ctions of development
costs for that areas, and the Alaskan Beaufort Sea related to the upcoming
joint state-federal lease sale. Consultations wvre made directly with
Alaskan and Canadian operators with interests in these areas, and Alaskan
operators interested in the Bering Sea OCS. It :ihould be emphasized that
in-depth research on production technologies and related costs for the
Bering Sea basins and Norton Sound in particular has only begun in
recent years.
II. Published Data Base
It is appropriate to briefly describe the published data base that is
available on petroleum development costs for frortier areas in general.
The North Sea cost data base includes the “North Sea Service” of blood,
Mackenzie & Co. which monitors North Sea petroleum development and
conducts economic and financial appraisals of North Sea fields. The
Wood, Mackenzie & Co. reports provide a breakdowu and scheduling of
capital cost investments for each North Sea field. All. Little, Inc.
(1976) have estimated petroleum development costs for the various U.S.
(3CS areas, including Alaskan frontier areas, and have identified the
costs of different technologies and the various components (platforms,
pipelines, etc.) of field development. The results of the A.D. Little
study have also been produced in a text by Mansvelt Beck and Wiig (1977).
Gulf of Mexico data has provided the basis for several economic studies
of offshore petroleum development (National Petroleum Council, 1975;
Kalter, Tyner and Hughes, 1975). Gulf of Mexico cost data has been
extrapolated to provide cost estimates in more severe operating regions
through the application of a cost factor multiplier. For example, Bering
Sea (ice laden area) cost estimates for exploration and development have
been developed using cost factor multipliers of 2.3 (exploration) and 3.7
(development) as defined by Kalter, Tyler and Hughes (1975). This
approach has been used in this report to provide a comparison among
estimates.
●
B-2
Other important cost data sources include occasional economic reports and
project descriptions in the Oil and Gas Journal, Offshore and various
industry and trade journals, and American Petroleum Institute (API)
statistics on drilling costs. A problem with some of the cost data,
especially estimates contained in technology references, is that they do
not precisely specify the component costed. Thus, a reference to a
platform quoted to cost $100 million may not specify whether the estimate
refers to fabrication of the substructure, fabrication and installation
of the substructure, or the completed structure including topside modules.
Another problem is that the year’s dollars (1975, 1976, etc.) to which
the cost estimate is related is often not specified.
III. Cost and Field Development Schedule Uncertainties
As stated elsewhere in this report, the purpose of the economic analysis
is not to evaluate a site specific prospect with relatively well known
reservoir and hydrocarbon characteristics but to bracket the resource
economics of the lease basin which comprises a number of prospects that
will have a range of reservoir and hydrocarbon characteristics. To
accomplish this requires a set of standardizing assumptions on reservoir
and hydrocarbon characteristics and technology (see Chapter 3.0). The
facilities cost data, presented in Tables B-1 through 13-7, have been
structured to accommodate this necessary simplif~cation.
It should be emphasized that in reality field’development costs will vary
considerably even for fields with similar recoverable reserves, production
systems, and environmental setting. Some of the important factors inthis variability are reservoir characteristics, quality of the hydrocarbon
stream, distance to shore, proximity of other fields, and lead time (from
discovery to first production). For example, platform process facility
costs can vary significantly with reservoir characteristics including
drive mechanism, hydrocarbon properties, and anticipated production
performance. Analytical simplification, however, requires that costs
vary with throughput while the other parameters are fixed by assumption:
The available cost data is insufficient to provide all these economic
sensitivities. Other factors also play a role in field development costs
TABLE B-1
PLATFORM COST ESTIMATES INSTAL1.ED3
Water Depth cost $ Millions 1979Platform Typez met ers I feet Midrange Value’
Modified Upper Cook 15 50 70Inlet Steel Jacket
Modified Upper Cook 30 100 130Inlet Steel Jacket
Modified Upper Cook 46 150 160Inlet Steel Jacket
1 A midrange value is given here. In the economic analysis, a lowestimate of 25 percent less than this value and a high estimate of 50percent greater than this value were investigated. Explanation of thisrange is presented in the text.
2 Sensitivity for numbers of well slots or production throughput isaccommodated by taking the low range value for platforms with 24 sless, and midrange value for 25 slots or more.
3 In addition to fabrication in a lower 48 yard, tnese estimates “the cost of platform installation which involves site preparation,setdown, pile driving, module lifting, facilities hsok up, etc.
ots or
ncludetow out,
Sources: Dames & Moore estimates compiled from various sources includingWood, Mackenzie & Co., 1978; A.D. Little, Inc., 197$; Bendiks, 1975; Peat,Marwick, Mitchell & Co., 1975; Offshore, November, 1978; Department ofEnergy, 1979 (see text).
●
●
●
●
9
●B-4
TABLE B-2
ARTIFICIAL ISLAND COST ESTIMATES
Platform Typel
Gravel Island
Gravel Island
Caisson Retainedg
Process/Storage/Loading Island
Waterm e t e r s
7 . 6
15
2 1
Depthfeet
25
50
70
cost $ Millions 1979Midrange Value’
24
60
150
i Island specifications include 213 meter (700 feet) working surfacediameter, 7.6 meter (25 feet) freeboard, and 4:1 side slopes:
z Gravel island costs can be anticipated to be extremely variable sincecosts are principally dependent on gravel availability, haul distance, andconstruction technique.
s Offshore terminal includes 244 meter (800 feet) diameter island, threemillion barrel crude storage, ship loading facilities, and crew quarters(Dome Petroleum, Ltd., 1977a and b).
Sources: Dames & Moore estimates compiled from various sources includingdeJong and Bruce, 1979a and b; Dome Petroleum, Ltd., 1977 and 1978 (see text).
B-5
TABLE B-3K
PLATFORM EQUIPMENT AND FACILITIESCOST ESTIMATES OIL PRODUCTION
Pe;ztlCa~pa;ity cost $ Millions 1979Platform Type2”’ Midrange Valuel
Modified Upper Cook 25 80Inlet Steel Jacketand Gravel Islandq 25-50 100
I I 50-100 I 160 I
‘ See No. 3, Table B-l.
z It is assumed that associated gas is not produced to market and is usedto fuel platforms with the remainder reinfected.
3 It is also assumed that a reservoir pressure maintenance programinvolving water injection will be required.
‘ Process equipment to be placed on gravel island nay have difficult con-figuration and installation techniques, but there is insufficient data toindicate differences in costs from modular topside facilities installed onsteel platforms.
*
●
Sources: Dames & Moore estimates compiled from various sources includingWood, Mackenzie & Co., 1978; A.D. Little, Inc., 1975; Department of Energy,1979 (see text).
●
B-6
TABLE B-3B
PLATFORM EQUIPMENT AND FACILITIES COST ESTIMATESNON-ASSOCIATED GAS PRODUCTION
Peak Capacity cost $ Millions 1979Platform Type Gas (MMcFD) Midrange Valuei
Modified Upper Cook 200-300 40Inlet Steel Jacket
300-400 55L
‘ See No. 3, Table !3-1.
Sources: Dames & Moore estimates compiled from various sources includingWood, Mackenzie & Co., 1978; A.D. Little, Inc., 1976; Department of Energy,1979 (see text).
B-7
TABLE B-4
DEVELOPMENT MELL COST ESTIMATES
WellWell Type meters
762
1,524
2,286
2,500
5,000
7,500
2.0
3.0I
4.0 I‘ See No. 3, Table B-1.
2 It is assumed that the well is deviated and a single completion.
Sources: Dames & Moore estimates compiled from various sources includingWood, Mackenzie & Co., 1978; API, 1978; Gruy Federal, Inc., 1977; Bendiks,1975 (see text).
●
B-8*
TA8LE B-5A
MARINE PIPELINE COST ESTIMATES
Average Cost Per Ilile’ $ Millions 1979Diameter Low Midrange High
20-29 3.5 4,7 7.0
10-19 2.6 3,3 5.0
<lo 1.7 2.0 3.0
1 High estimate used for short pipelines less than 16 kilometers (10miles). Midrange estimate used for medium length pipelines 16 to 32kilometers (10 to 20 miles). Low estimate used for long pipelinesgreater than 32 kilometers (20 miles).
Sources: Dames & Moore estimates compiled from various sources includingWood, Mackenzie & Co., 1978; API, 1978; O’Donnell, 1976; Eaton, 1977; Oiland Gas Journal, August 14, 1978; Oil and Gas Journal, August 13, 1979;Offshore, July, 1977; Offshore, July, 1979 (see text)”
B-9
TABLE B-5B
ONSHORE PIPELINE COST ESTIMATES
Average Cost Per Mile $ Millions 1979Diameter Midrange Valuel
20-29 4.0
10-19 3.0
<lo 1.9
i See No. 1, Table B-l.
Sources: Dames & Moore estimates compiled from various sources includingOil and Gas Journal, August 13, 1979 (see text).
●
●
9-=10
TABLE B-6
OIL TERMINAL’ COST ESTIMATES
Peak Throughput(MBD)Z
<1oo100-200
200-300
300-500
Total Cost Per Mile $ Millions 1979Midrange Value’
260
340
600
750
1 The shore terminals costed here are assumed to perform the followingfunctions; pipeline terminal (for offshore lines), crude stabilization,LPG recovery, tanker ballast treatment, crude storage (sufficient forabout 10 days’ production), and tanker loading for crude transshipmentto the lower 48.
2 There is a cost index which ecwates facility ccst with daily bblcapacity - the terminal costs cited here range- frcm about $1,800 to $3,000per daily bbl capacity.
‘ See No. 1, Table B-1.
Sources: Dames & Moore estimates compiled from various sources includingWood, Mackenzie & Co., 1978; Duggan, 1978; Cook Inlet Pipeline Co., 1978;Shell Oil Co., 1978; Global Marine Engineering Co., 1977; EngineeringComputer Opteconomics, Inc., 1977 (see text).
B-II
●TABLE B-7
ANNUAL F ELD OPERATING COST ESTIMATES
2 Platform Field, Pipeline-Terminal
3 Platform Field, Pipeline-Terminal
40
80
115
Sources: Ilames& Moore estimates compiled from various sources includingWood. M a c k e n z i e & CO., 1 9 7 8 ; A.Il. L i t t l e , I n c . , 1975; Gruy Federal, lnC.,
●
1977’(see t e x t ) .
B-12
such as market conditions. The price an operator pays for a steel
platform, for example, will be influenced by national or international
demand for steel platforms at the time he places his order, whether he is
in a buyers or sellers market. Similarly, offshore construction costs
will be influenced by lease rates for construction and support equipment
(lay barges, derrick barges, tugs, etc.) which will vary according to the
level of offshore activity nationally or internationally.
The cost estimates presented in Tables !3-1 through B-7 are essentially
an amalgam of estimates from various sources in some cases made by
rationalizing several pieces of sometimes conflicting evidence. It
should further be emphasized that there is considerable variation in both
published and industry data; this is understandable given the unknowns of
operating in the harsh environment of the northern Bering Sea. Because
of these significant variations, low, medium, and high values for the
various petroleum facilities and equipment were defined. A low estimate
of 25 percent less than the mid-range (medium) value and a high estimate
of 50 percent greater than this value were selected and used for economic
screening.
In general terms, -
can be anticipated
the Beaufort Sea.
the Reaufort Sea, “
ield development costs in similar water depth ranges
to be somewhat greater than Cook Inlet but less than
Norton Sound does not have as severe ice conditions as
ength of ice season, or such ,3 remote location in
terms of logistics.
All the cost figures cited in Tables B-1 through B-7 are given in 1979
dollars. Cost figures from the various sources have been inflated to
1979 dollars using United States petroleum industry indices.
Briefly discussed below are the principal uncertainties relating to the
cost estimates’ for the various facility components.
111.1 Platform Fabrication and Installation (Tables B-1 and B-2)
In addition to Upper Cook Inlet type steel platforms, we have evaluated
the economics of artificial gravel/sand islands based on cost experience
R-13
of exploration islands in the southern Canadian Beaufort Sea and projec- 0 “
tions for permanent production islands in both the Canadian and Alaskan Q
Beaufort. The cost of such islands is very sensitive to the cost of
gravel/sandwhich is related to the haul distance of the fill. Our
estimates have taken gravel costs at the upper end of costs for dredged
borrow in the Canadian Beaufort which involves haulage by dump barge.
In addition to the cost sensitivity of water depth for steel platforms,
factors such as design deck load and number of well s?ots also affect
cost . To provide, more cost sensitivity than just water depth, we have
taken the low range investment value for smaller platforms (24 well slots
or less) and the mid-range value for platforms with 25 or more well
slots. With a fixed initial productivity per well and with the maximum
number of wells per platform related to reservoir depth, tttis assumption *also provides for some sensitivity related design deck load as related to
throughput capacity of process equipment.
111.2 Platform Process Equipment (Tables B-3Aand B-3B~
As noted above, our platform process facility costs (Tables B-3A and B-3B)
vary with throughput and assume that other parameters are fixed as noted
on the tables.
111.3 Marine Pipeline Cost Estimates (Table B-5A~
Particularly uncertainty exists on marine pipeline costs that may be
incurred on northern Bering Sea projects as suggested by the range of
projections for Arctic and sub-Arctic areas.
Pipelayinq costs iri the Norton Basin are uncertain or may vary
considerably because:a
e The lack of support base sites are a particular problem in
Norton Sound; resupply and support of Norton Basin pipelaying ~
operations may have to be provided by an Aleutian Island base*
considerably extending resupply turnaround schedules.
aB - 1 4
o while most projects could be completed in one summer season
in the northern Bering Sea given the distances to shore and
typical laying rates, extensive burial of pipelines or extended
resupply lines could extend a project into a second season
especially for the discovery sites more distant from shore
(100 kilometers [60 miles] plus).
9 The geologic and oceanographic hazards of Norton Sound may
require special engineering or re-routing especially close to
shore and at landfalls where ice is a problem. This will
increase pipeline costs compared with open water areas to the
south.
s The short summer weather window, fall storms, and possible
extended supply lines contribute to project risk and hence
uncertainty of project costs especially for longer lines.
Other factors being equal, the per unit costs (i.e. per meter or kilometer’
of pipelaying will decrease with the length of the line except where a
line is too long to lay in one season. Shore approaches and landfalls
are particularly expensive and mobilization/demobilization costs corn]
a greater portion of project costs the shorter the line. B e c a u s e of
these factors, we have assumed the high range cost for short lines (’
than 16 kilometers [10 miles]), mid-range value for intermediate
lengths (16 to 32 kilometers [10 to 20 miles]) and low estimate forlong lines (over32 kilometers [20 miles]).
111.4 Onshore Pipelines (Table B-5B)
rise
ess
Onshore pipeline costs in the Norton Sound area can be anticipated to
be significantly greater than projects in the Cook Inlet area because
of the special engineering requirements of construction in permafrost
terrain, remote location, possibily greater environmental sensitivity,
and other factors related to construction in a harsh environment. costestimation relies on the experience of Alyeska and Cook Inlet develop-
ment, and projections related to the Alcan, Polar Gas, Pacific Alaska
Q-lq
LNG (Cook Inlet), Kuparuk field development, and Ileaufort Sea lease sale
projects. In comparison with lower 48 costs, Norton Sound onshore
pipelines can be anticipated to cost four to six times as much.
111.5 Oil Terminal Costs (Table B-6)
Oil terminal costs will vary as a function of throughput, quality of crude,
upgrading requi~ements of crude for tanker transport, terrain and hydro-
graphic characteristics of the site, type, size and frequency of tankers,
and many other factors. Permafrost terrain, sea ice, and remote location
will impose significantly greater costs on terminal construction than a
similar project in the Cook Inlet area or lower 48. There is little cost
experience to project terminal costs in Alaska except Cook Inlet and
Alyeska. Further afield, there is the North Sea experience of the
relatively remote Flotta and Sullom Voe terminals located in the Orkney
and Shetland Islands, respectively.
Two studies have addressed the economics of terminal siting and marine
transportation options in the Bering Sea (Global Marine Engineering,
1977; and Engineering Computer Optecnomics, 1977). A third study addres-
sing these problems was conducted for the Alaska lil and Gas Association
(AOGA) and is currently proprietary.
As indicated on Table B-6, it is assumed that the
bines the functions of a partial processing facil
for
Iv.
The
tanker transport) and a storage and loading tf
Methodology
marine terminal com-
ty (to upgrade crude
rmi nal .
cost tables presented in this appendix were the basic inputs in the
economic analysis. Each case analyzed was essentially defined by reserve
size, production technology, and water depth. To cost a particular case,the economist took the required cost components (field facility and
equipment components) from Tables B-1 through B-7 using a building blockapproach; in some cases a facility or equipment item was deleted or
substituted. The construction of cases for economic evaluation is
explained in Chapter 3.0, Section 3.4.
al
9
B-16
The cost components of each case are then scheduled as indicated in the
examples presented in Table B-8. The schedules of capital cost expendi-
tures are based upon typical development scheduies in other offshore
areas modified for the environmental conditions of Norton Sound assuming
certain assumptions on field construction schedules (see discussion
below).
v. Exploration and Field Development Schedules
This appendix discusses the assumptions made in defining the exploration
and field development schedules contained in thf scenario descriptions in
Chapters 5.0, 6.0, 7.0, and 8.0. These schedul~s are basic inputs into
the economic analysis (scheduling of investments) and manpower calculations
(facility construction schedules) as described in Chapter 3.0. As with
facility costs, exploration field construction schedules are somewhat
speculative due to unknowns about technology, er,vlronmental conditions
(oceanography, etc.), and logistics. Nevertheless, the economic and
manpower analyses require a number of scheduling assumptions based upon
the available data and experience in other offshore areas.
Figure 6-1 illustrates the field development schedule for a medium-sized
oil field involving a single steel platform, pipeline to shore, and shore
terminal in a non-ice-infested but harsh oceanographic environment such a
Lower Cook Inlet, the Gulf of Alaska, or North Sea.
The sequence of events in field development from time of discovery to
start-up of production involves a number of steps commencing with field
appraisal, development planning, and construction. The appraisal process
involves evaluation of the geologic data obtained (see Figure B-2) from
the discovery well, followed by a decision to drill delineation (appraisal)
wells to obtain additional geologic/reservoir information for reservoir
engineering. There is a trade-off between additional delineation wells
to obtain more reservoir data (to more closely predict reservoir behavior
and production profiles) and the cost of the drilling investment. Usingthe results of the geological and reservoir engineering studies, a set of
development proposals are formulated. These would also take into account
B-17
9
TABLE B-8
EXAMPLE OF TABLES USED IN ECONOMIC ANALYSIS CASE - SINGLE STEEL PLATFORM, PIPELINE TOSHORE TERMINAL, WATER DEPTHS 15 to 46 METERS, 2,286 METER OIL RESERVOIR
A. SCHEDULE OF CAPITAL EXPENDITURES FOR FIELD DEVELOPMENT - PLATFORM COMPONENT
I Year AFactlity/ActivitY
iP1 atfonn Fabrication 40
P1 atfonn Equipment 40
PI atfonn Instal latfon
Oevel opment We] 1s’ - 48’
Miscellaneous
er Decision to Oevelop - Percent of Expenditurez 3
I I I I50 1050 10
100
30 (12) 40 (16) 30 (12)
33 I 33 I 34 I I I‘ Example presented is for 48 wel 1s based on assumption of two rigs working at a complet ion rateof 45 days Der ri Q: for cJi fferent numbers of wel 1s the expenditures are prorated augroximat ly at theassumed ~omplet io; ‘rate.z Figure in parentheses is the number of wel Is dri 1 led per year.
F!. SCHEDULE OF CAPITAL COST EXPENDITURES - PIPELINE AND TERMINAL COMPONENTS
Year After Decision to Develop - Percent of ExpenditureFacillty/Activity
Oil Pipeline (10 to 20 inch) 30 7032 km (20 miles)
Terminal (100-300 MBO) 5 40 40 15
Source: Dames & Moore
‘aa
B-18
9mL
c
c
—
P
oLn—
N
u
—
u
—
%
Ll-
0
—
#-W
44
u.
ma
-0!=a
VI. m
(Asu
z’a)>0vW
alc
.1-
.“a)>J?n n
8-19
FIGURE B-2
INITIAL INPUT INFORMATION
t t\
DISCOVERY _ _ _WELL
FIELD {EVALUATION
—— —.
a
DECISIONPOI:iTS o
.*— — — —. — —-‘1
— — —— — D,
Possible
-—— —/=— —— — — — “k- — — —l-
‘[kRESERVOIRSTUDIES +
J
DEVELOPMENTPROPOSALS
TI I
DEVELOPMENTPLANS
t
ECONOMICEVALUATION
●
+
—. D,
.(-m<D
I tSELECTION OF — _A DEVELOPMENT
—— ——‘4
i DETAILEDI ENGINEERING1 STUDIES
;I
-1Further
DecisionsStarting Point
for Unitisation Discussions t
THE APPRAISAL PROCESS~~~rce: Birks (1978) B-20
locational and environmental factors such as meteorologic and oceanographic
conditions; The development proposals involve preliminary engineering
feasibility with consideration of the number and type of platforms,
pipeline vs. offshore loading, processing requirements, etc.
As illustrated in Figure B-2, the development proposals are screened for
technical feasibility and other sensitivities, reducing them to a small
number to be examined as development plans. These are further screened
for technical, environmental, and political feasibility. An economic
analysis of these plans is conducted similar to that conducted in this
study , In the economic evaluation, facilities, equipment, and operating
expenditures are costed, and expenditures and income scheduled. A ranking
of development plans according to economic merit is then possible and
weighed accordingly with technical, environmental, and politica~ factors
to select a development plan for subsequent engineering design. The
feasibility appraisal process is complete. At this time, the operator
will make a preliminary go, no-go decision.
If the decision is made to proceed, the operator will conduct preliminary
design studies which involve marine surveys, compilation of detailed
design criteria, evaluation of major component alternatives, and detailed
economic and budget evaluation. Trade offs between technical feasibility
and economic considerations will be an integral part of the design
process. The preliminary design stage will be concluded when the operator
selects the prefered alternatives for detailed “design. The decision to
develop will then be made.
The field development and production plan will then have to pass regulatory
agency scrutiny and approval. In the United States, the operator will have
to submit an environmental report, together with the proposed development
and production plan, to the U.S. Geological Survey in accordance with U.S.
Geological Survey Regulation S250.34-3, Environmental Reports presented
the Federal Register, Vol. 43, No. 19, Friday, January 27, 1978.
In terms of the effect upon the development schedule, delays due to regu’
tory agency review, environmental requirements, etc. can not be predicte(
n
a-
B-21
with accuracy for possible Norton Sound discoveries. The time that may
elapse from discovery to decision to develop is field specific and also
difficult to predict as in the number of delineation wells required to
assess the reservoir. tlowever, these factors are
report by the schedule assumptions cited below.
with the decision to develop final design of fat-”
accommodated in this
ities and equipment
commences and contracts placed with manufacturer:, suppliers, and con-
struction companies. Significant investment exp~nditures commence at
this time. Front-end engineering and design would take from one to two
years following decision to develop, depending u~on the facility/equipment.
Design and fabrication of the major field component -- the drilling and
production platform would take about three years for a large steel jacket
such as Chevron’s North Sea Ninian Southern Platform (Hancock, White and
Hay, 1978). Onshore fabrication of a steel jacket platform will vary
from about 12 to 24 months depending upon size and complexity of the
structure (Antonakis, 1975). An additional seven months of offshore
construction will be required for pile driving, mxiule placement and
commissioning.
A critical part of offshore
offshore work in the summer
field development is ;cheduling as much
“weather window” and timing of onshore
construction to meet deadlines imposed by the weal;her window. In the
Gulf of Alaska or North Sea, platform tow-out and installation would
occur in early summer, May or June, to permit max~mum use of the weather
wi ndow. If the weather window was missed or the platform was installedin late summer, costly delays up to 12 months in length could result.
Construction of offshore pipelines and shore terminal facilities are
scheduled to meet production start-ups which is related to platform
installation and commissioning and development well drilling schedules.
If shore terminal and pipeline hookups are not planned to occur until
after production can feasibly commence, offshore loading facilities maybe provided as an interim production
operator has to weigh the investment
potential loss of production revenue
system (and long-term backup). The
costs of such facilities against the
from delayed production.
O.*
@
*
*o*
B-22
Development well drilling will commence as soon as is feasible after
platform installation. If regulations permit, the operator may elect
to commence drilling while offshore construction is still underway even
though interruptions to construction activities on the platform occur
during “yellow alerts” in the drilling process (Allcock, personal communi-
cation, 1978). The operator has to weigh the economic advantages of
early production vs. delays and inefficiencies in platform commissioning.
Development drilling will generally commence from six to 12 months after
tow-out on steel jacket platforms. Development wells may be drilled
using the “batch” approach whereby a group of wells are drilled in
sequence to the surface casing depths, then drilled to the 13-3/8-inch
setting depth, etc. (Kennedy, 1976). The batch approach not only improves
drilling efficiency but also improves material-supply scheduling. On
large platforms, two drill rigs may be used for development well drilling,
thus accelerating the production schedule. One rig may be removed after
completion of all the development wells, leaving the other rig for
drilling injection wells and workover.
V.1 Potential Problems with Norton Basin Exploration and
Field Construction Schedules
The weather window in the northern 13ering Sea varies from four to six
months. Although it is possible to install a steel platform and add the
deck and modules (or utilize a completely integrated deck) in one open
water season, the schedule is nevertheless very tight. ‘In the case of
Upper Cook Inlet, platform installation, deck installation, and module
lifting was generally accomplished in about four months and development
drilling was able to commence sometime between October and January. With
ice breaker s/Jpport to tow the platform around Point 8arrow in early
summer, Dome Petroleum believes that it is possible to install and
commission a monotone production platform (with integrated barge-mounted
deck units) in one season in the southern Canadian Beaufort Sea and
commence development drilling the following winter. Gravity structureswould r e q u i r e l e s s i n s t a l l a t i o n t i m e t h a n p i l e d s t r u c t u r e s .
A particular problem in Norton Sound be the provision of the necessary
B-23
logistical support required during the season of ice cover to assisto
facilities hook up, platform commissioning, and development drilling
activities. There is insufficient deck space to accommodate drilling and *
other supplies necessary to support these activities unassisted during
the winter months. If this problem can be surmounted, development
driling could commence within 12 months of platform installation.
The construction schedule for an artificial grave-. production island is
less certain since none have been built. In deeper water (about 18
meters [60 feet]), Canadian experience indicates Ihat a production island
would probably take two seasons to construct. For soil stabilization
purposes, it may also be advisable to leave the i:,land undisturbed for
one season. In the scenarios, we have assumed th?,t gravel island construc-
tion would commence the year following decision to develop and take two
summer seasons. Barge-mounted integrated process units would arrive on
site in the second open water season; these units could be either floated
into a basin left open in the island which would then be closed and
drained, or the units could be skidded on to the island. In comparison,
the steel platform development schedule assumes t?,at the platform is
installed in the second year after the decision tc develop. During the
first year, the platform is being fabricated in a lower 48 ship yard.
(Construction of a gravel island can commence a year earlier since it is
built of local materials and only requires mobilization of a dredge
spread; a caisson design may require longer because of the need to
fabricate the caissons.)
Because of the uncertainties in construction schedules and the risk of -
missing the summer weather window, economic cases are evaluated which
assume one or two years delay in the field development schedule.
Another schedule, problem concerns the weather window restriction
exploratory drilling. With the potential resources as indicated
U.S.G.S. estimates and, assumincj U.S. historic find rates (number
o n
by the
ofexploration wells per significant discovery), it is apparent that either
a significant number of rigs would”be on location in Norton Sound each
summer or the exploration program would extend beyond the initial five
.*
●
B-24 w
Significant capital expenditures commence the
“decision to develop”; that year is year 1 in
expenditures in the economic analysis.
year following
the schedule of
Steel platforms in all water depths are fabricated and installed
within 24 months of construction start-up. Platforw installation
and commissioning is assumed to take ten months. Development
well drilling is thus assumed to start about ten months after
platform tow-out.
Steel platform tow-out and emplacement is assumed to take place
in June.
Artificial island construction commences the year after deci-
sion to develop in June and takes two summer seasons. Process
equipment is installed in the second summer and development
drilling commences ten months later.
Platforms sized for 36 or more well slots are assumed
two drill rigs operating during development drilling.
sized for less than 36 well slots are assumed to have
rig operating during development well drilling.
to have
Platforms
one dril
Drilling progress is assumed to be 20 days per oil development
well per drilling rig, i.e. 12 wells per year for 762 meters
(2,500 feet) reservoirs, 30 days per well (12 per rig per year)
for 1,524 meter (5,000 feet) reservoirs and 45 days (8 per rig
per year) for 2J286 meters (7,500 feet) reservoirs.
Production is assumed to commence when about ten of the oil
development wells have been drilled and when about 6 gas wells
have been completed.
Well workover is assumed to commence five years after produc-
tion start-up.
Oil terminal and LNG plant construction takes between 24 and
36 months depending on design throughput.
B-25
year tenure of OCS leases. Only one well per rig could be reasonably
anticipated to be drilled assuming a four month season unless targets
were particularly shallow. An extension of the drilling season through
ice breaker support and use of ice-reinforced rigs could extend the
season and increase the number of wells accomplished per rig. (Dome
Petroleum has extended the drilling season beyond that feasible for
conventional rigs using ice-resistant drillships dnd ice breaker support.)
In the shallower waters of Norton Sound, the use of gravel islands could
also extend the drilling season. The key problems relating to extension
of the drilling season by these methods are not technical but rather
economic and environmental. Extension of the season into spring and fall
occurs at critical biological seasons in the migration and/or other
aspects of life history of some species, the impact upon which would
depend on the location of drilling activities.
*
VI. Scheduling Assumptions
Based upon a review of technology
mental conditions in the northern
have been made on exploration and
d e v e l o p m e n t s c h e d u l e s i n C h a p t e r s
data, industry experience, and environ-
Bering Sea, the following assumptions
field development scheduling (see field
6.0, 7.0, and 8.0 and economic assump-
tions in Chapter 3.0, Section 3.6).
e Exploration commences the year’ following the lease sale (i.e.
1983); all schedules relate to 1983 as year 1.
e An average completion rate of four per exploration/delineation
well is assumed with an average total well depth of 3,048 to
3,692 meters (10,000 to 13,000 feet).
e The number of delineation wells assumed per discovery is two
for field sizes of less than 500 mmbbl oil or 2,000 bcf gas,
and three for fields of 500 mmbbl oil and 2,000 bcf gas and
larger.
9 The “decision to develop” is made 24 months after discovery.
B-26 *
APPENDIX C
●
APPENDIX C
PETROLEUM TECHNOLOGY AND PRODUCTION
This appendix reviews offshore petroleum technology that may be applicable
to Norton Sound petroleum development, in particular Arctic and sub-Arctic
engineering. Data for this review comes from published sources including:
(1) Professional and trade journals such as Journal of Petroleum
Technology , Offshore, World Oil, Proceedings of the Offshore
O*
a
Technology Conference (various years),
Petroleum Engineer.
(2) Dames & Moore data files.
Oil and Gas Journal, and
(3) Discussions with engineering and exploration departments of oil
companies operating in Alaska and in the Canadian Arctic.
(4) Interviews with petroleum industry construction companies.
Data on petroleum facility costs was obtained concurrently with data
gathering in petroleum technology.
Throughout this discussion, it should be borne il mind that Norton Sound
is a frontier area yet to experience the drill bit (offshore). In fact,
only one offshore well has been drilled in the wpole Bering Sea - a
C.O.S.T. well drilled in St. George’s Basin in 1976 by Atlantic Richfield
and partners. Furthermore, only recently has research focus turned to
Norton Sound as regulatory agencies and industry have concentrated on
areas further up on the lease schedule list such as the Beaufort Sea and
Gulf of Alaska. A C.O.S.T. well is scheduled to be drilled in Norton
sound in the summer of 1980 using a jack-up rig.
This appendix commences with a brief review of offshore Arctic petroleum
experience that will enable petroleum development in Norton Sound to be
placed in the context current state-of-the-art engineering. A description
●o
c-1 9
1 of the environmental constraints to petroleum development in Norton Sound
then follows. The remainder of the appendix describes the various production
systems, particularly platforms, that may be suitable to develop Norton Basin
petroleum resources.
I. Offshore Arctic Petroleum Experience
1.1 Canadian Beaufort Sea
Exploration drilling in the Canadian Arctic startec in the Mackenzie
Delta in the mid-1960~s. After several years of extensive onshore
exploration, which resulted in the discovery of commercial gas reserves,
exploration extended offshore into the Beaufort Sea (Figure C-l). The
first well was drilled in the winter of 1973-74 frcm the artificial
island, Immerk B-48, in 3 meters (10 feet) of water. To date, artificial
islands have been constructed in the Beaufort Sea to a maximum water
depth of 20 meters (65 feet). The most recent artificial island is
“Issungnak” located in 20 meters (65 feet) of water, 25 kilometers (15.5
miles) from shore; the island is of sacrificial beach design requiring 3.5
million cubic meters (4.6 million cubic yards} of fill and two summer
seasons (1978 and 1979) to construct.
Exploration drilling with ice-strengthened drillships started in deeper
waters (over 30 meters [100 feet] in 1976). Three drillships were
bperating in the Canadian Beaufort Sea in the summ~rs of 1977 and”1978.
A fourth ship was scheduled to join the fleet late in the 1979 season.
At the end of the 1977 drilling season, three gas discoveries and one oil
discovery had been made by the Dome ships. Four wells were spudded and
drilled to varying depths in 1978 and the 1979 drilling program called
for re-entry of four wells and spudding of four new wells. The recent
announcement of a major oil discovery at the M-13 Koponoar well indicates
significant promise for hydrocarbon production in this area.
1.2 Alaskan Beaufort Sea
In contrast to the Canadian Beaufort, Alaskan Beaufort Sea exp” oration
ted to ice islands near the Colville delta (Union Oil) andhas been lim
C-2
,.,
ALASKA
LU21FICATLANTIC OCEAh
CEAN
/
0’KILOMETERS MILES
—SC) URCE: CRC) ASI%%E , 1977.
Figure C-1
●o
)several wells drilled from gravel pads in shallow water in Prudhoe Bay
on existing state leases. The joint State-Federal lease sale scheduled
for December 1979 will, of course, change the picture.
1.3 Canadian Arctic Islands
The other major arctic frontier is the Canadian Arctic Islands. Explora-
tion drilling started in 1961 and off-ice drilling began in 1974 on the
landfast ice that covers the sea between the islands for up to 11 months
of the year. The first offshore well, Panarctic’s Helca N-52, was
successfully drilled from a reinforced ice platform in 130 meters (429
feet) of water, 13 kilometers (9 miles) from shore. Six gas fields have
been discovered to date in the Sverdrup basin of the Arctic islands.
Polar Gas has proposed a 48-inch, 5,330-kilometer-long (3,200-mile)
pipeline, which would involve crossing several deep inter-island channels,
to transport the gas to southern Canadian and eastern United States
markets. Proven arctic island gas reserves could now exceed the threshold
of 20 trillion cubic feet required to support this pipeline with the
announcement made in early 1979 of the Whitefish H-63 discovery.
A LNG system, the Arctic Pilot Project, has been proposed as an interim
transportation system to take arctic gas to market by Petro-Canada. That
system would involve construction of a gas pipeline across Melville
Island, a LNG plant and marine loading terminal, and a LNG shipping
system employing ice-breaking tankers (World Oil, November, 1977). A
pilot project involving the first arctic subsea production system and
submarine pipeline was completed in 1978. An 18-inch, 1.3-kilometer-long
(0.8-mile) pipeline was constructed to take gas from Panarctic’s Drake
F-76 gas well, situated in 58 meters (185 feet) of water to shore.
1.4 Eastern Canadian Arctic
Exploration drilling has begun off the east coast of Labrador in Canada
and in the Davis Strait between Greenland and Canada. Ice-free periods
i vary from 365 days per year in the south to about 100 days in the Davis
Strait. These cc-free periods permit the use of conventional drilling
c-4
platforms such as semi-submersibles and drillships. The main contrast
with other ice-infested waters is the threat of icebergs. An average of
15,000 icebergs a year calve from west Greenland; some weigh over 3
million tons and have drafts over 260 meters (858 feet). Techniques for
iceberg avoidance and handling have been developed which involve radar
tracking and towing systems using support vessels. Because of the threat .@of iceberg collision and the need for rapid move-off, dynamically posi-
tioned drillships or semi-submersibles are better suited to this area
than systems using mooring lines. Drilling on the Canadian portion of
the Labrador Sea and Davis Strait south of 60°N started in 1971; explora-
tion began on the Greenland (Danish) side in 1976. Because of the
iceberg threat, only dynamically-positioned vessels are permitted to work
in Greenlandic waters. By the end of 1978, five wells had been completed
on the Greenland side of the Davis Strait, while drilling was scheduled
to commence on the Canadian side north of 60°N in the summer of 1979.
II. Environmental Constraints to Petroleum Development
11.1 Oceanography
11.1.1 Introduction
The oceanographic setting of the proposed sale area is primarily within
the Chirikov and Norton Basins, north and west of St. Lawrence Island..
Climatically, this region is in a transition zone. During the summer,
winds are from the south and west and a maritime climate prevails; in the
winter, wind direction changes to the north and east and a continental
climate is more in evidence.
This area is ice free less than half the year. Little is known of the
oceanographic conditions under the ice. There is some evidence toindicate that oceanographically, summer and winter may differ markedly.
For instance, except for smaller eddies due to islands and irregular
coastlines, the flow everywhere appears to be toward the north during the
summer. On the other hand, a general cyclonic (counterclockwise) motion
may be established in the Bering Sea during the winter.
*
Q
*
.c-5 ●
Also the proposed sale area is strongly influenced by the Yukon River
which discharges 5,660 cubic meters per second (200,000 cfs) annually
into the southeast portion of this region. The Yukon is responsible for
the creation of a large delta on the southern side of Norton Sound and
most of the recent sedimentation in this region is probably due to the
introduction of material by this giant river.
11.1.2 Bathymetry
Shallow water conditions characterize the entire sale area. The deepest
portion, in the northwest corner, is just over 49 met~rs (160 feet). A
channel 46 meters (150 feet) deep lies just off the eastern edge of St.
Lawrence Island. A deltaic fan created by the Yukon River forms a large
shoal generally less than 15 meters (50 feet) deep in the southwest
portion of Norton Sound. The Sound has an average depth of 18 meters
(60 feet) (Cacchione and Drake, 1978), and is relatively uniform except
for an anomalous channel located just south of the shoreline of Nome.
The bottom of the Sound slopes gently from east to west.
As a result of the growth of the polar ice caps and increased continental
glaciation, the Bering Sea has become a subaerial feature several timesin the last million years. The last time only about 11,000 years ago.
11.1.3 Circulation
The general flow through the Bering Sea is northward. Water is transported
from the North Pacific through the Bering Strait into the Chukchi Sea.
Superimposed on this flow are several medium-sized eddies which result
from the presence of St. Lawrence Island and from irregularities in the
Siberian and Alaskan coastline. In addition to these fluctuations, there
are other topographically induced variations in the northward transport
as the flow is funneled past St. Lawrence Island and through the Bering
Strait, the flow is slowed when passing certain large embayments such as
Norton Sound and the Gulf of Anadyr. A minor southward flow is indicated
in the western Bering Strait during the summer (U.S. Weather Bureau and
U.S. Navy Hydrographic Office, 1961). Also during the winter a cyclonic
circulation pattern may tend to become established under the ice (Figure C-2).
c-6
NOW: unaer-ice currerw vetocmea
——=—=S= Q.urent direction well established have bean poorly documented.
I --- + Hvpotheticrd current direction or sporadic flow Adapted from O C. B.rbmk, 1974. 6u8v8mfd S9dimorIt TmurJcw7 ● IIQ$ Dwc.si-tiari in Al@tan Soared Watwa with S$VSial Emphuls on Rmnota %aing bv
0.8-2.4 Mmn Currerrt velocity ram iII krm (f Knot= O.s 1 M1O*C) tlM ERTS-1 %t?llit@. ad U.S. Wes!hor 8ureau and u.S. NOW HydraaraphicOffice, 1961. Cllmatolosirsl and Occmoeraphic Atlu for Msrinw8. Voium@ Il.NorefI Padflc Oman: and G.J. Potoc$kv. 197S. Aladwn ArzQ 16- md SOd#v IcoFo-athq Guide.
Source: Selkregg, 1974, Fig. 41
Figure C-2
SURFACE WATER CIRCULATION PATTERNIN SUMMER AND WINTER
*
Actual current measurements within the Bering Sea are quite limited. In
1967, measurements were made both north and south of the eastern side of
the Bering Strait. The southern station was approximately 96 kilometers
(60 miles) from the Strait in a water depth of 48 meters (157 feet). The
mean flow was 31 cm/sec (0.6 knots) at 13 meters (43 feet) and 21 cm/sec
(0.4 knots) at 35 meters (115 feet). During the monitoring period,
several reversals of relatively short duration were noted; being more
common in the lower meter. The reason for these reversals is not known.
Apparently they are not associated with tides nor with local wind patterns
(Coachman et al., 1975).
Coachman et al., (1975), report that in 1968 three current meters were
deployed in the Bering Sea -- one just off Northwest Cape on St. Lawrence
Island. Thirty hours of continuous data showed a mean current of 36 to
41 cm/sec (0.7 to 0.8 knots) with a semidiurnal variation of from 10 to
26 cm/sec (0.2 to 0.5 knots). During the same cruise, 30 hours of data
were also obtained from Anadyr Strait, west of St. Lawrence Island. The
mean current was approximately 51 cm/sec (1 knot) with semidiurnal varia-
tions equal to that average current.
The third station was well north of St. Lawrence Island, approximately
56 km (35 miles) southeast of Cape Krigugan on the Russian mainland. This
station was occupied for approximately 25 hours. The mean flow was much
less -- on the order of 21 cm/sec (0.4 knots) and there were no apparent
semidiurnal variations in the flow.
According to Coachman et al. (1978), several current meters were deployed
during the winter of 1976 and 1977 in the Bering Sea. Of the 13 recovered,
data from three have been processed. Two were in the strait between St.
Lawrence Island and the mainland to the east; the other was in the Bering
Strait. These current meters were placed a distance of 9 meters (30
feet) from the bottom and remained in place over the entire ice season
producing long-term records in excess of seven months. The meters in thevicinity of St. Lawrence Island showed a long-term mean of 51 cm/sec (1
knot), generally to the north or slightly east of north. There were
large north-south variations in excess of 51 cm/sec (1 knot) at both
C-8
diurnal and semidiurnal periods. The current meter deployed in the
Bering Strait showed a long-term average of 10 cm/sec (0.2 knots) with
variations also in excess of 51 cm/sec (1 knot). However, these variations
could not be tied directly to tidal periods witn the possible exception
of a trace of semidiurnal signal. Additional data remain to be analyzed
from this program and should shed light on many questions about the
general circulation of the Bering Sea.
o
~ In addition tothe”area just north and east of ‘;he eastern tip ofSt.
Lawrence Island, Norton Sound makes up the eastern half of the proposed*
sale area. Its physical oceanography, like that of the Bering Sea, is
only beginning to be investigated. It has alretldy become evident,
however, that the dynamics of Norton Sound are i’ery complex. Norton
Sound can be divided into two distinct regions -- the western part, which
has good communication with the general circulation of the Bering Sea;
and the more isolated eastern portion which apparently has only limited
communication with the main portion of the Norton Sound. The latter
apparently represents an anomalous feature in that it has bottom water
that is colder and more saline than the water at. the same depth in the
western part of the Sound. Muench et al. (1977), speculated that this is
a remnant feature created during the formation clf ice in which more
saline cold water is formed as surface water fr~ezes. The more dense
water then sinks and owing to the limited mixing in this part of the
Sound, remains after the ice melts. It then probably becomes mixed and
replaced by water during the next freeze-up.
The U.S. Weather Bureau, U.S. Navy Hydrographic Office (1961), and Meunch
et al. (1977), have indicated that the western portion of Norton Sound is
characterized by a counterclockwise gyre. Cacchione and Drake (1978)measured currents over an 80-day ice-free period at a location 59 km
(37 miles) south ofNome. They obtained an average value of about
5 cm/sec (0.1 knot) at a distance 1.4 meters (4.5 feet) off the bottom in
17 meters (57 feet) of water. This current was directed slightly east of
north and had associated with it semidiurnal tidal fluctuations up to
36 cm/sec (0.7 knots). These tidal variations tended to be in the
east-west direction. They also found that on at least one occasion the
9
0
c-9 ●
northerly current was so intensified by southern winds as to essentially
mask the tidal variations in the flow. The data that were taken by
Cacchione and Drake south of Nome would tend not to support the cyclonic
gyre theory proposed by Muench et al. (1977). Additional meas(]rements
were taken by Muench et al. (1977) southwest of Cape Darby which showed
tidal variations of about 36 cm/sec (0.7 knots). However, the mean flow
was essentially zero.
Cacchione and Drake (1978) compiled data collected by C. H. Nelson and
divided the Norton Sound area into three distinct current regimes. The
area east of a line from Cape Darby to Stewart Island has been assigned a
mean current of 7.5 cm/sec (0.15 knots). Between that line and a line
between Sedge Island south to a point approximately 24 km (15 miles) west
of Kawanak Pass has been assigned a value of 15.3 cm/sec (0.30 knots).
The area west of that line to a line approximately 50 km (31 miles) west
of Point Clarence south-southeast to a latitude 63° 30’ N and longitude
67° 00’ W has been assigned a mean current of 20.6 cm/sec (0.40 knots). -
taken over relativelyThe measurements that established these areas werl?
short time periods from an anchored vessel. As such, they have tidal
information associated with them. However, with d sufficient quantity of
data points, these may average out, although the !Iumber of data points
necessary to accomplish this averaging is uncerta-.n. Thus, these values
should be viewed with a certain amount of sceptic;sm. In the next few
years, additional field work in, and further analysis of, existing data
for Norton Sound will be done. Its complexity is already evident. Over
much of the year, its dynamics are dominated by tidal motions superimposed
on a mean flow resulting from the Alaska Coastal Current. During ice-free
periods, local winds have significant effects on the current regime. The
Yukon River, no.doubt., effects the physical oceanography of Norton Sound
as does the formation and melting of the seasonal icepack.
11.1.4 Ice
The proposed lease area is ice free, on an average only four months of
c-lo
the year (Figure C-3, U.S. Meather Bureau and U.S. Navy Hydrographic
Office, 1961 ). Average break-up and freeze-up periods, as seen in Fig-
ure C-4, are from late May to early June and from late October to mid-
November, respectively (State of Alaska, 1974).
It has been reported that pack ice in the Bering Sea can be approxi-
mately 12 meters (40 feet) thick (Nelson, 1978). Nelson also reported
that Norton Sound floe ice can be up to 2 meters (6.5 feet) thick.
However, other estimates such as by the National Ocean Survey (Coast
Pilot, 1979) suggest thicknesses less than this. The shorefast ice
extends shoreward of the 10-meter (33 feet) contour. Pressure ridges
form near the contact between the fast and floe ice. Keels on these
ridges are quite capable of severely gouging the sea bottom. Such
gouges are particularly prevalent across Norton Sound as illustrated
in Figure C-5. Ice scars over 1 meter (3 feet) deep have been noted
side-scan sonar images (Ne?son, 1978).
11.1.5 Tides
on
The tides in this northern portion of the Berinfj Sea, depicted in Fig-
ure C-6, are small with diurnal ranges from about 0.45 to 1.2 meters
(1.5 to 4 feet). Except for the diurnal tides flowed in the southeast
portion of Norton Sound, the tides are of the mixed type, that is,
there are two unequal highs and two unequal lows during each lunar day.
Tides, which are long progressive waves, propagate northward through the
Bering Sea and Bering Strait. Upon approaching Norton Sound, they
proceed around the bay in a counterclockwise direction.
As previously described, the circulation in Norton Sound is strongly
influenced by tidal fluctuations. Tides in this shallow bay may be the
primary force responsible for ice motion and scouring. The effect, if
any, that ice might have on tidal currents is not known.
11.1.6 Waves and Storm Surge
The generation of waves in deep water depends on fetch, wind speeds, and●o
C-11
I .4-. ~.“.. ..+ I
.8 I
xd’ - I
*. ‘.- ,0- ‘- 1
LI.d-. ~.“.,u-.
n
C33
01 Cowaq. ODE.0,10.4 C.a”erap scattered
0,50.7 Co”ecam Broke.
0.8.0.9 Co”emge close
1,0 coverage [“0 wa,erl cO.ZO1!dW?rJor 1s!1
— A.apr.m male MumwrI Ezte.r of 0.1 .x GraterC.men I,.: 80.
No,, T,, W, ,= ,,,mt, .,, t.,w o“ obmrva,ro”, <ecardado.,r m a n , deem,,. la Cu.m”!el ma, ..,, *CM,, fromda, m a,” ma ,,,, , . , . O . . . 0 , . the ml(uen,, d cn2.lQ”qCl!ma,!e md .C,anq,am!c m.d,,,om. %,,,*,,LI W*, .,!Cn may M mmUn,arQd &vo.d ,., ..- I,m, t
%,,, U S We,,.?. Surau and u S. Now H. CI,OV,O”<COfka. 1961. Cl,”u,.,ng,d .nd o.-cpt,,. Aluf ,.,Ma..-. w r Il. Nom. P.cdk 0c8m,I — . — _ _ _ _ _
, /.
—
#--
Figure C-3,
Source: Sel kregg,1974, Fig. 43
SEASONAL ICE CONDITIONS IN THE BERING AND CHUKCHI SEAS
C-12
I Nome (Norton Sound)Breakup 4 1 2 8 - 6 / 2 8 ~V9. 5 /29 (50)FreezeuR 10/1 3-1 2/13 Ava. 11/12 (50)
+Freezeup 10/13-12/26 Avg. 11/10
\I Savoonga (Bering Sea)
1-13reakup 4125-6il 7 Avg. 5/26 (lo)Freezeut) 9/30-12/13 Avg. 11/19 (10) K ~+e~~,
. ...,
.
~,o:-- -, \\N
:. %hKlV9U\ ‘t% .$4’”: II -
r.— —.. -.. — _Golovin (Golovnin Bay)Breakup 5/1 3.6/1 4 Avg. 5/23 (6)Freezeup 10/8-11/19 Avg. T 1/2 (6)
~--
A
/
.__. .— )J
‘. !.4‘6-
t~
(-L. ..) \
$Y(
[1’
( .—\, ~
( ‘1+/7 \ \
,,. /-:2 !6 “‘ St. Mi~h;el (Norton Sound)Breaku~ 5/1 9-7/3 Avg. 6/9
I Freezeup 10/10-12/7 Av~. 11/10 (53)0 w.. v
r------40 m 120 w Mbm,lashhvmetrv m h!hcms. 1---Unalaldeet (Unalakleet River) I
Breakup 4 / 2 6 - 5 1 3 0 A v g . 5/1 “f
--l
(14)Sourc-: U.S. *8 - OOedOrlc SUwav, 1@. Unif.d Sw- - ~lim 9, Mic ● nd Amtlc C-m,Mnkc. ~ ~ m Scwfofi * and AIaoks. Univwsitv. 197S. ~uka~ *: SWIW Slfak-kv Freezeup 10/8-11/19 Avg. 10/25apw -I - SloI.=si@ Ch=mw of Al@tan tinfsl Zom * Muhu WWmmnMt. 31 maw -— _._-..-__~~’~
Figure C-4
$F?EAKUP AND FREEZEUP DATA, NORTHWEST REGION
(Modified from Sel kregg, 1974, Figure 44)
o
●
9
●
6
6
0IA.P
6
. —
1?0 168 166 164 162
Figure C-5
-
ICE GOUGING IN NORTHEASTERN BERING SEARose d i a g r a m s r e p r e s e n t t r e n d a n d n u m b e r o f g o u g e s ; d a t a a r e t r e n d sa n d n o t i n d i c a t o r s o f a b s o l u t e m o t i o n . D i v i s i o n i n t o a r e a s 1 - V]i s b a s e d o n z o n e s o f s i m i l a r t r e n d i n g g o u g e s . (Modified from Nelson,1978, Figure E-6.)
i“
Ob
~ Diurnal tide
—9- Cotidai lines lNumerals indicate time of high water of the
_ Proposed Lease Sale Area BoundaryDrinclpal lunar sem!diurnal tide-lines connect points ofequal t%meof high orlowwater.1
Note: Mean range = Average semidiurnal range occurringbetween mean high and mean low water.
Figure G=%
TIDAL ELEVATIONS AT SELECTED I-CICATIONSWITHIN AND NEAR PROPOSED SALE AREA
(Modified from $elkregg, 1974, Figure 47. )
C-15
wind duration. In the relatively shallow and protected waters of the
~orthern Bering .Sea, water cle?th and wave direction need also be considered.
St. Lawrence Island restricts the propagation of sea waves from the west
and southwest into much of the sale area. Norton Sound is exposed to
waves from the southwest but these waves are severely attenuated owing to
its shallow waters. The north-eastern portion of the sale area is
exposed to waves from the south but again waves must develop in, and
propagate through water depths of less than 30 meters (100 feet).
The bottom friction associated with such shoal water does not permit
waves to attain the deep water characteristics. For instance, accordingto the sverdrup-Munk-~retschnei der wave prediction method (U.S. Army,
CERC, 1975) a 74 km/h (40-knot) wind blowing over a 370 km (200 nautical
mile) fetch for sufficient duration to utilize the entire fetch could
generate waves with a significant height of almost 5 meters (16 feet).
However, other conditions being equal, but with wave generation occurring
in 29 meters (95 feet) of water (an appropriate value for this area) the
significant height would be reduced to 2.3 meters (7.5 feet) (U.S. Army,
CERC, 1975). This reduction is due only to bottom friction but additional
diffraction caused by topographic features such as St. Lawrence Island
and the Yukon Delta will further restrict waves in the Bering Sea.
A maximum significant wave height 2.3 or 2.4 meters (7.5 or 8 feet) given
the appropriate set of meteorological conditions, could translate (assuming
that these waves are Rayleigh distributed) into a maximum wave of about
4.3 meters (14 feet).
Waves are important to small boat operations, in moving sediments in
shallow water and in the coastal and nearshore processes. They can also
be important when coupled with storm surge. Such storm tides are increases
in sea level above astronomical tide levels on or near the coast. The
low-lying coastal regions and shallow water make much of the Bering Sea
shoreline particularly susceptible to this type of storm flooding.
Records of storm surges are incomplete, however, Nome was severely
damaged in 1913 and again in 1946 by such storms (Gute and Nottingham,
1974). In 1974, a major storm occurred in the northern Bering Sea. A
C-15
surge from that storm has been noted from Port Clarence to St. Michael
Island (Challenger et al., 1978); Elevations above mean sea level have
ranged from over 3 meters (10 feet) in the Port Clarence to Cape Rodney
area to over 4.6 meters (15 feet) in the eastern portion of Norton Sound.
Also, a 1977 storm produced a debris line approximately 2 meters (6.5
feet) above MSL. Such surges would be particularly important to coastaldevelopment.
11.1.7 Oceanographic Comparisons with Upper Cook Inlet and
Implications for Platform Design
To date the only offshore area sufficiently rich in petroleum resources
to warrant development has been the upper Cook Inlet. It has been
assumed, based on the available input from industry sources, that the
offshore structures for’the Bering/Norton region would likely be similarto those used in Cook Inlet. In light of this probability, it seems
appropriate to compare the oceanographic conditions of the two areas.
Except for the majority of Norton Sound, Cook Inlet is the shallower
area. However, tidal ranges within Cook Inlet are about on the order of
magnitude greater thari those in the Bering/Norton region.
Ice conditions may also be markedly different betlieen the areas. In the
northern region, ice is present six or seven months of the year and may
be 30 cm (1 foot) or more thicker than in the south-central region.
Also, ice coverage is probab?y more extensive than in Cook Inlet.
Although the preponderance of the ice is continually in motion, fast ice
does exist within a few kilometers of the shoreline. While ice strengthand coverage may be less in Cook Inlet, the large tidal currents of over420 cm/sec may create a structural loading situation as severe as any inthe Bering/Norton region. Greater knowledge of ice conditions for the
northern region needs to be obtained before this can be said with certainty.
Some structures in Cook Inlet have been designed for an extreme wave of
8.5 meters (28 feet). This wave may be larger than that which could
actually develop within the Inlet but, in fact, the most severe loading
o8
●a
)
condition probably results from the combined effects of ice and tidal
currents. Owing to the presence of St. Lawrence Island and relatively
shallow water, design waves within the northern lease area may be consid-
erably less than 6.1 meters (20 feet). In any e~ent, as with Cook Inlet,
the greatest structural loads probably result frcm moving ice.
While conditions within the two regions appear to differ in several
important areas, it may be that actual design characteristics between the
two are not all that dissimilar. This means that knowledge gained from
development in the Inlet will greatly facilitate development in the
Bering/Norton area.
11.2 Geology and Geologic Hazards
11.2.1 Tectonic Setting
Norton Sound is a large coastal embayment approxiinately 250 kilometers
(150 miles) long and 125 kilometers (75 miles) wide that is located in
the northern part of the Bering Sea immediately south of the SewardPeninsula. The Norton Sound region lies within a Mesozoic fold belt.
Although the region is located well away from the major plate boundaries
in southern Alaska, the area does experience tectonic adjustment due to
plate interaction. Major transcurrent faults, first active during the
Mesozoic period, show significant right internal displacement through
recent times. This tectonic adjustment is due to right lateral shear
stress caused by a rotational component of the tectonic plate interaction
(lloodward-Clyde Consultants, 1978). The major transcurrent fault in the
area, the Kaltag fault and its offshore continuation are shown on Fig-
ure C-7.
The historic seismicity of the Norton Sound region has been compiled byWoodward-Clyde Consultants (1978) for the years 1964 through 1976. The
13-year record of seismicity, which includes 38 events, does not have any
earthquakes within magnitudes of above 6. Major earthquakes with magnitudes
of 6 or greater have been reported in the area prior to 1959; three
occurred in one sequence between February and May 1928 and two in another
couzc)N1-
●
0
cozc1l=.
*o
sequence in April 1958 (Woodward-Clyde Consultants, 1978). The Kaltag
fault and its unmapped projection into the ‘iukon-Kuskokwim delta area is
considered as the major source of earthquakes in the Norton Sound region
(Woodward-Clyde Consultants, 1978).
11.2.2 Regional Geology
The Norton Sound region is underlain by Precambrian through Quarternary
strata of varying Iithologies. These strata have been grouped into broad
belts of rocks distinguishable by age and lithology (Fisher et al.,
1979). Immediately north of Norton Sound, Precambrian slates and Paleozoic
metamorphic and sedimentary rocks are exposed across much of the Seward
Peninsula. West of Norton Sound and along its southern boundary,
Mesozoic sedimentary volcanic rocks predominate. Localized intrusions
of Mesozoic through Cenozoic plutonic rocks isolated patches of Tertiary
sedimentary rocks and Quarternary basalts can be found throughout the
Norton Sound region. The onshore geology of the Northern Bering Sea
region is present on Figure C-8.
Projection of the described rock units offshore along structural trends
is aided by interpretation of geophysical data which indicates that
similar rock units probably underlie Norton Sound and its adjoining
structural basin, the Norton Basin (Nelson et al., 1974; Fisher, 1979).
Norton Basin, a structural depression adjoining Norton Sound on the west,
is filled with a thick sequence of probable late Mesozoic through Cenozoic
strata. The basin, which began to develop during late Cretaceus, formed
as a pull-apart feature (separation of structural blocks) along the right
lateral Kaltag fault (Fisher et al., 1979). Associated west-northwesttrending normal faults cut across the basin forming grabens ‘which contain
the thickest basin fill of up to 7 km (4 miles). These grabens separated
by hosts over which basin fill is generally less than 3 km (1.9 miles)
(Fisher et al., 1979).
C-20
1-
iiiill0
r
. .
.JURAS - CR ETA- TERT”IARY OUATER-
Slc CEOUS N A R Y
4\
‘\\,\
‘z
c1
●
~._.~—’’----v----JPRECAh.I - P A L E O.
BRIAN Zolc
@ *
—- -.,..
●0
●
t
Three major strati graphic units are recognized within Norton Basin. These
major units described by Holmes et al., (1978) consist of:
(1) A lower unit of probable upper Cretaceus which
deeper parts of the basin.
(2) Overlain by a thick sequence of lower to middle
occur in the
Tertiary
sedimentary rocks.
(3) An upper unit of upper Tertiary and Quaternary sediment and
sedimentary rocks.
The areas of Norton Sound not part of the structural basin are underlain
by a comparably shallow bedrock platform which slopes gently basinward.
The platform is cut into probable Paleozoic-Mesozoic bedrock and overlain
by predominantly late Tertiary through Quarternary sediment.
Two styles of faulting are recognized within the Norton Basin (Fisher et
al., 1979). To the west of the Yukon Delta, the west-northwest trending
normal faults are easily connected among the seismic lines. The latter
group of faults are either highly discontinuous or have variable strikes
so they converge and diverge in a complex pattern (Fisher et al., 1979).
Where strikes can be determined, the faults located north of the Yukon
delta strike
1979.
11.2.3
west-northwest, like those west of the delta (Fisher et al.,
Surficial Geolo~
Pleistocene Ice Ages occurring during the past two to three million years
have caused major world-wide fluctuations of sea level. During periods
of lower sea level much of the Norton Sound area was subaerial, this
indicated by the broad accumulations of organic rich peat deposits
(Kvenvolden, 1978). The Yukon River and other rivers during this time
extended their courses across the continental shelf and delivered most of
their load to the deeper abysal basins. Glacial deposits immediately
south of Nome and north of St. Lawrence Island indicate that glaciers
c-22
extended beyond the present shoreline although the Pleistocene glaciation
of the Seward Peninsula was far less extensive than that of the Brooks
Range and southcentral Alaska. With rising sea level most of the sedimen-
tary load was retained in the river channel or deposited in the river
delta area. Holocene sediment from the Yukon River has blanketed most of
the floor of the Norton Sound with several meters (5 to 15 feet) of
silt. The modern delta of the Yukon river is a relatively young geologic
feature having formed since 2500 years ago when the river course shifted
north to where it enters the Norton Sound (Dupre and Thompson, 1979).
Interpretation of shallow, high-resolution geophysical records for the
Norton Sound and Basin areas (Nelson and Hopkins, 1972) and for the
offshore area south of Nome (Tagg and Green, 1973) indicate the presence
of many relicit sedimentary features. Outwash fans, buried alluvial
channels, beach ridge, and glacial moraines have been recognized in the
geophysical records. The number of relief features, their form and
aerial extent indicate a very complex Pleistocene history for the area.
Surface and nearshoe faults
margin of Norton Basin, but
determine as strong current
scarps (Johnson and Holmes,
are prominent along the entire northern
Holocene fault activity is difficult to
scour may be preserving or exhuming old
1978) . Some faults are believed to be
from scarps on the sea floor, and some offsets of the acoustic basement
can be correlated with fault traces in the overlying basin fill (Holmes
et al., 1978).
11.2.4 Geologic Hazards
Potential geophysical hazards
and reported upon by the U.S.
Thor and Nelson, 1978; Fisher
within Norton Sound have been investigated
Geological Survey (Nelson et al., 1978;
et al, 1979). Recognized potential geologic
hazards can be grouped into the general categories of tectonic, sediment
instability, and erosional and depositional hazards. Each of the described
potential geologic hazards are discussed as well as any design implications
that these hazards may represent for petroleum facilities primarily
platforms, gravel islands, and pipelines sited in the area.
w
eo●
C-23
11.2.4.1 Tectonism
Surface and nearshore faults are prominent along the entire northern
margin of Norton Basin and are present along its southern boundary.
}{owever, recent activity is difficult to determine as many of the fault
scarps may be preserved or exhumed by current scour (Johnson and Holmes,
1978). Seismic events probably associated with the major transcurrent
faults in the Norton Sound area and observed displacements of onshore
features along the Kaltag fault east of the Yukon delta (Woodward-Clyde
Consultants, 1978) indicate that the Kaltag fault and its associated
faults are probably active. Dupre and Hopkins {1976) have recognized
faults, photo linears,
Yukon delta plain that
viously mapped bedrock
When siting structures
and joint sets within Quarternary deposits of the
are aligned with a parallel to some older, pre-
faults.
or routing pipelines in the Norton Sound, active
fault zones should be avoided if at all possible. Rupturing of the
ground surface along a fault zone can shear pipelines and damage platforms
or gravel islands. In addition, ground shaking which is generally more
severe closest to the earthquake source, can induce soil instabilities
and cause the undermining of these structures.
11.2.4.2 Soil Instability
Surface and near surface soil instabilities in the Norton Sound region
may occur in areas which have high concentrations of gas-charged sediment
or in areas which have sediment susceptibility to liquefaction.
There are two types of gas-charged sediment in the Norton Sound area:
(1) thermogenic, occurring in a local area 40 kilometers (25 miles) south
of Nome, and (2} biogenic, in a wide area of north central Norton Sound
(Thor and Nel son, 1979). Gas charged sediments can be recognized in a
variety of ways; generally through geophysical, geochemical, or geotech-
nical means. The method of detection of gas-charged sediment is discussed
at length in Nelson et al., 1978; Holmes et al., 1978; and Kvenvolden et
al., 1978.
,.
[.74
Thermogenic gas, predominantly Coz, is generated deep within the basin
probably through the thermal conversion of limestone. The gas migrates
upward along fault planes. Geophysical records indicate a large accumu-
lation of thermogenic gas (9 km [5.5 miles] in diameter) approximately
100 meters (339 feet) below the sediment surface in an area approximately
40 km (65 miles) south ofNome (Thor and Nelson, 1979).
Biogenic gas is generated within the organic-rich peaty muds which were
formed subaerially in the Norton Sound area. Apparently, the high
concentration of gas-charged sediment, as indicated by acoustic anomalies
and by gas craters, occur only where the freshwater peaty muds are
overlain in a relatively thin (1 to 2 m [3.3 to 6.6 feet]) layer of
recent muds (Thor and Nelson, 1979). Gas craters are lacking where the
recent mud is thick or where the mud grades into sand north of St.
Lawrence Island (Fisher et al., 1979). Gas venting and crater formation
commonly occur during peak storm periods when the surficial soils are
subject to rapid changes in pore pressure. The rapid pore pressure
changes are due to either the super elevation of the water level (storm
surge) or to cyclic loading by storm waves.
The fine-grained sand and coarse-grained s
of Norton Sound are highly susceptible to
seismically induced cyclic loading (Fisher
are generated over the long stretch of the
lt wh-ich form the substrate
iquefaction due to wave or
et al,, 1!379). Waves which
Bering Sea appear capable of
inducing sufficient loading to liquify Norton Sound sediment to a depth
of 1 to 2 meters (3.3 to 6.6 feet) (Fisher et al., 1979).
The aerial extent of the gas crater fields and isopachs of Holocene muds
are presented on Figure C-9. As shown on Figure C-9, large areas of theNorton Sound contain gas-charged sediment or have sediment susceptible to
liquefaction. Platforms or gravel islands built on these types of soils
may undergo rapid settlement due to the soils’ low bearing strength or
susceptibility to liquefaction, Due to the broad extent of these potential
soil instabilities, it may not be possible to avoid these areas and,
therefore, special design precautions should be taken for structures
sited in the area. It may be possible to penetrate through the zone of
o
9
*
●
9
CT1=
Is
A...- 1
.+., - c-i
\. -i -_—.. — — /
-b”--------
J\—_ —____ . >“—------ ____ - . J :
.-.—. . ..-_ . . . . .
.— ____ .._-_ . . . . !2?.., .-— — —________ >’. > 5!-. —--- _______ .___. ~ J> ‘“ :’+ “.’7 w-T------------- ., ___ _____ a a,
..1
+ ‘- ‘“”-”--—.. — _ ____ . 4’”
)(.- “Q)------ .._ -_ . . .:>;—. .> ~
-------- . ———— _______ f/c k—--- .—--— - -----
L5’\
---- -- —. —-— _____ :. km .-.~d -”--–-”” —-— .-.. — . .. ___ . d
,. ..- Ccl2,/. . . . . . . ..-— ___ .,4? T.:. _ . . . . . ________ -----
/
;._J -’ -- f%___–1 “c>y..fi-:::”I-:rL:”.7:.: ___n .>, .-
C.1to
7w
Q
gas-charged
deeper bear
penetration
of gas from
sediment or sediment susceptible to liquefaction and reach
ng strata. However, care shou’d be exercised in siting as
to a deeper bearing strata may act as an avenue for release
a deeper source.
11.2.4.3 Erosion and Deposition
Erosional features in the surficial sediment of ~orton Sound are associated
with ice gouging and/or bottom scour due to unidirectional current flow
(wind induced current, oceanographic current) and to oscillating current
flow (wave induced currents). These erosional features are shallow-generally
developed into the upper meter (3.3 feet) of surficial sediment.
Ice gouging in bottom sediment is found everywhere throughout northeastern
Bering Sea beyond the shorefast ice zones where kater depths are generally
less than 20 meters (66 feet) (Thor and Nelson, 1979). Ice gouging has
been noted at depths as great as 30 meters (99 feet). Strong bottom
current can maintain and enlarge the ice gouge furrows.
Scour depressions associated with bottom current occur most frequently
in areas where there are micro and macro bathymetric obstructions which
may cause construction of current flow and result in current scour. .
Structures such as pipelines or electrical lines should be placed below
the maximum reach of current scour and/or ice gouging which is thought to
be approximately 1 meter (3.3 feet). In the Norton Sound area there may
be long-term, wide spread surficial sediment level changes, and consequently,
a deeper burial depth may be required.
Structures such as platforms or gravel islands may intensify currentflow around the structure and cause current scour to depths greater than
observed around natural features. These structures should be protectedto a depth beyond the maximum reach of current scour.
Much of the sediment introduced by the Yukon River into Norton Sound is
bypassing the Sound and entering the Chukchi Sea to the north (McManus et
9
●
*
●
●
9
al. , 1977) . Sediment pathways through Norton Sound are indicated by long
linear features which commonly have bedfarm (ripple marks and/or sand
waves) along their surface. Sand waves as high as 1 to 2 meters (3.3 to
6.6 feet) have been reported within Norton Sound. The sedimentary
material introduced by the Yukon River is being transported through
Norton Sound probably by some combination of oceanographic current and
wind and wave induced currents.
Zones of ripple marks bedforms observed in Norton Sound are presented on
Figure C-10. Structures such as grave? islands may impede current flow on
the updrift side of the structure and cause the der)osition of sediment.
The may necessitate expensive maintenance dredging. Proper siting of the
structure away From zones of active sediment transport and/or consideration
of island shapes may mitigate many of the deposition effects. Pipelines
laid across zones of sand waves may he undermined and unsupported during
sand wave mitigation. These areas should be avoided if possible or the
pipeline should be buried beneath the lowest probable sand level.
Figure C-10 presents a composite of potential geologic hazards recog-
nized in the Norton Sound area. As shown on the figure, there are a wide
variety of potential geologic hazards which span much of the Norton Sound
area. Very few areas are free of potential geologic hazards. The
negative effects of many of these hazards such as erosional/depositional
processes and surficial sediment instabilities can be reduced or eliminated
by burying pipelines or founding structures on the solid substrata
beneath the surficial soils.
11.3 Bioloqy
11.3.1 Terrestrial-!4etland Habitats of the Coastal Zone
The coast?ine along Norton Sound and the northwest 5ering Sea is narrow,
bench-like in formation, and mostly Qverlain with mud, sand or gravel
substrates. The terrain often rises steeply beyond the tidal zone,
forming a border of cliffs or bluffs. The associated foothills, drainage)“ slopes, and plateaus support a variety of vegetative types including
C-28
9
.z1.,
h
J
‘)m.c-0
‘5
u).c)C
c-29
upland spruce-birch forest, high shrub, moist tundra, and alpine tundra.
The lcw-?y~ng areas of Pastoi B~y, Norton !?ay, from Cape Rodney to Point
Spencer, and from Cape Prince of Males to Shismaref Inlet provide exten-
sive wetland habitat. In the northeast Bering Sea, Big and Little Diomede
Islands, King, Sledge, St. Lawrence, and Punuk Islands, rising abruptly from
the submarine plain, are bounded by rocky wave-cut cliffs. Seldom exceeding
305 meters (1,000 feet) in elevation, these islands are characterized “
by rolling uplands of alpine and moist tundra. The eastern part of St.
Lawrence Island is a lake-dotted lowland of wet tundra. Figure C-n shows
the vegetative zones along the coastl~nes of the Norton Sound area.
I?any small maxmals are year-round residents of the Norton Sound coastal
region. A few large mammalian species, e.g., brown bear and moose, are
seasonally dense along the coast or in the nearby river valleys though
some are also present throughout the year. hong small mammals the
tundra hare, red fox, arctic fox, land otter, arctic ground squirrel,
mink, wolverine, and weasels are found near shore from Ikpek Lagoon north
of Cape Prince of Wales to the Yukon River Delta, i.e., throughout the
entire length of mainland shoreline of the lease sale area. Muskrat, red
squirrel, porcupine, snowshoe hare, beaver, and lynx are a“
distributed though some species do not occur northof Cape
of Cape Stephens. Marten and coyote are present in more 1
tion (Kl inkhart, 1978; Somerville and Bishop, 1973).
Coastal beach and delta areas are the prime habitat of the
so widely
Nome, or west
mited distribu-
arctic fox.
St. Lawrence Island supports a large breeding population as do other
offshore islands of the Norton Sound region. Arctic fox populations
fluctuate widely, partly in response to the population cycles of lemmings.
Other prey include seabird eggs and marine mammal carrion, both ashore
and far out on pack ice. Arctic foxes are attracted to areas of human
use by improper garbage disposal. The potential of a rabies epidemic and
its spread to humans is created when fox numbers become large (Dames &
iloore, 1978a).
Brown (grizzly) bears occur in low density throughout Seward Peninsula
and the interior beyond Norton Sound. The population has been estimated
C-30
-%
o
oa<3u(n
zoi-a0z
E0?
●
●
---
2,-
cu
c
at about 400 individuals. In May or JurIe, they tend to forage on carrion
along the coast. Black bear are found along the e~stern coast of Norton
Sound between Shaktoolik and Kliktarik, and along the intervening river
valleys into Nulato Hills. About 200 black bears are estimated to live ~
in this area (Kl inkhart, 1977).
Moose occur in river valleys throughout the coastal and interior lands of
the Norton Sound region. Females also calve in flaodplajn areas. Of the
five major overwintering areas, i.e., those containing about 70 percent
of the moose population (Klinkhart, 1977), the Unalakleet River Valley is
most likely to be affected by OCS development activities. Unlike in
other drainages, the Unalakleet bottomland is used by moose down to the
river mouth. The critical dependence of moose on bottomland for overwinterir
and calving may constrain any OCS development in the Unalakleet drainage.
Other important overwintering areas are shown in Figure C-II.
The overwintering grounds of the western Arctic caribou herd include the
coastal region of Norton Sound approximately between Egavik in the north
and Pastolik in the south (Somerville and Bishop, 1973). Beyond these
locations, the herd ranges to the interior. Densities
coast are low.
Musk oxen occur in small populations on Seward Peninsu’
of caribou on the
a, in the York and
Kigluaik Mountains. They seasonally occupy coastal areas near Cape Rodney,
Cape Douglas, and Ikpek Lagoon.
In low density and roaming in small packs, wolves are found-in the
mainland coastal zone throughout the sale area, except west of Pastolik
on the southern coast of Norton Sound. Their southern distribution
coincides with that of caribou. On Seward Peninsula they are more
sparsely distributed than in the Nulato Hills. About 100 to 150 wolves
are thought to occupy this area (Klinkhart, 1977).
Among raptors, gyrfalcons, peregrine falcons, rough-legged hawks,
golden eagles, bald eagles, ospreys, and snowy and short-eared owls
found throughout the Norton Sound region and, with the exception of
are
peregrine falcons, also on St. Lawrence Island. Boreal and hawk owls,
and goshawks are restricted to forest habitats on the mainland. Willow
and rock ptarmigans are widespread in the coastal zone. More than 30
passerine bird species also occur here (Selkregg, 1976), ranging from
ravens to redpolls to warblers, and occupying both tundra and forest
habitats. Species found here which undergo intercontinental migrations
include the wheatear, arctic warbler, blue throat, yellow wagtail, white
wagtail, and three swallow species.
Mithin or adjoining the lease sale region are found major expanses of
waterfowl habitat. The coastal region surrounding Ikpek Lagoon has been
designated a key waterfowl area and classified as part of Bering Land
Bridge National Monument under the proposed Federal LandPolicy Management
Act (FLPMA) withdrawals of December 1, 1978. Much of the coastal area
surrounding Pastel Bay is occupied in high density by waterfowl. Part of
this area has been protected as the Yukon Unit of the Clarence Rhode
Wildlife Range. The remainder is proposed for federal protection as the
Yukon Delta wildlife refuge under the FLPMA withdrawals of November 16,
1978. Other high density waterfowl areas incluc(e the wetlands surrounding
Cape Denbigh, Moses Point, Koyuk, and Imuruk Basin. Medium or low
density waterfowl areas correspond to wet or moist tundra zones not
already mentioned.
The Clarence Rhode National Wildlife Range and remaining Yukon delta
produce nearly all of the whistling swans, emperor geese, cackling geese,
and white-fronted geese migrating to the Pacific flyway. Densities of
greater than 200 geese and black brant per square mile have been recorded.
Other common wetland species of the Norton Sound region include the.greater scaup, pintail, old squaw, American widgeon, green-winged teal,
common scoter, and Stellerls eider.
Bering Land Bridge National Monument
many migrant and resident birds. Of
encompasses critical habitat for
the 352 species known to occur in
Alaska, 137 have been recorded in this region. The wetlands of the
reserve include prime habitat for ducks, whistling swans, geese, and
sandhill cranes (Klinkhart, 1977).
9
●o
A common feature of many life histories of species strongly associated
with the marine habitat is the seasonal movement or migration tied to ice
cover in Norton Sound and the northeast Bering Sea. Movement of seals,
whales, and walrus, timing of breeding and reproductive success in
seabirds, and spawning of herring are among the phenomena keyed to
position, formation, and break-up of ice. With results of the ongoing
OCSEAP studies, knowledge is slowly accumulating as to the nature of the
dependence of these patterns with regard to vulnerability to disruption
by man. OCS development by challenging the time limits of the ice-free
period may interfere with these patterns during critical times or at
critical locations.
Seabirds
Seabird colonies of the lease sale area are concentrated on islands
rising from deep waters (St. Lawrence, Little Diomede, Fairway Rock, King
and Sledge Islands), and along the mainland shores north of Cape Douglas,
between Nome and Rocky Point, at Cape Ilenbigh, and between Golovin and
Cape Stephens. These areas and shallow water islands in Norton Sound
(Stuart, Egg, and Berboro Islands) which also support bird colonies
(Figure C-II) include 13 locations which have been proposed as marine
resource preserves for inclusion in the national wildlife refuge system.
As shown in Table C-1, the most dense and diverse colonies occur on
deepwater islands.
In addition to nesting habitat, these islands afford access to offshore
feeding areas in the northwest Bering Sea. I n a s t u d y r e p o r t e d b y Ramsdell
and Ilrury (1979) auklets were observed to feed in a broad semicircular arc
concentric with the western half of St. Lawrence Island. Other major feedin~
areas visited by seabirds lie between King and Sledge and Little Diomede
Islands. The only major foraging activities observed east of Sledge island
were found in a 32 kilometer (20-mile) band paralleling the Peninsular coast
between Sledge Island and Golovin Bay. This area overlies a deep channel
entering Norton Sound. Geographical variations in the use of forage areas
r- 2A
TABLE C-1
MAJOR SEABIRO COLONIES IN THE NORTON SOUND LEASE SALE REGION>BASED ON COLONY CENSUSES IN THE PERIOD 1966-1976
Colony Size No, of Dominant Speci es*Site (thousands) Species (descending rank)
St. Lawrence Island
Southwest Cape 549 11 CA, LA
Sevuokok Mountainnear Gambel 1 189 7 CA, LA
Cape Kagh-Kasal ik 22 9 CA, LA
Savoonga 89 5 CA, LA
Cape Myangee 631 3 CA, LA
Reindeer Camp 57 4 CA, LA
Other Offshore Islands
Little Diomede 1,261.6 14 LA, CA, CM, BLK
Fairway Rock 46.7 12 LA, TBM, CA, CM
King Island 245.9 13 LA, CM, TBM, PA
Sledge Island 4.7 13 CM, BLK, TBM, PC
Mainland Area
Bluff 46.0 9 CM, ELK, HP, TBM
Square Rock 3.9 7 CM, BLK, HP, GG
Cape Oarby 1.4 6 IHP, PC, GG, TP
Cape Oenbigh N. 5.2 9 CM, BLK, TBM, PC
Cape Oenbigh S. 7.2 8 CM, BLK. TBM, PC
Egg Island 2.8 9 CM, BLK, HP, TIIM
Source: Sowls and Nelson, 1977.
*Species abbreviations are as follows:
CA crested auklet TBM thick-billed murreLA least auklet BLK black-legged kittiwakePA parakeet auklet GC glaucous gullsCM common murre
PC pelagic comorantHP horned puffinPT tufted puffin
c-35
*
●
●o●
I
are keyed to drifting ice of the receding front, or to other areas of high
biological productivity. In June, birds forage to the northeast of St.
Lawrence Island, following masses of drifting ice ~s they move northwest past
Sledge and King Islands. In July, many birds are feeding in broad zones
around King Island, Fairway rock, and Little Diomede Island, north or north-
west of Gambell, and along the mainland coast from Cape Woolley to Golovin
Bay. In August, offshore feeding areas tend to shift to the west and south;
the waters of Norton Sound south of the coastal band mentioned above are freeof birds.
In winter the front of the ice pack is an important habitat for seabirds,
especially murres. Productivity there is significantly higher compared
with other Bering Sea waters (McRoy and Goering, 1974). Another ice-water
interface habitat utilized as a refugium by birds is the polynya, or area
of open water in the pack ice associated with islands (Divoky, 1977).
Breeding activities of seabirds in the Norton Sound region are cued by
the receding of pack ice and evidence is accumulating that the earlier
break-up occurs, the greater is seabird reproductive success (Ramsdell
and Drury, 1979). At break-up birds follow lead systems near breeding
sites or move to inshore areas that are free of ice. Early nesting allows
birds more flexibility in the recoupment of eggs lost to predation. Impor-
tant predators on eggs include humans, foxes, and ravens.
Intertidal and Shallow Benthos
The littoral and shallow sublittoral zones of the Norton Sound region
are marginally developed owing to winter ice scour. Proportionally abouthalf of the tidal zone substrates are soft (Table C-2). Removal or
disturbance of sessile marine organisms from hard substrates by ice is a
strong limiting factor in the development of rocky shoreline communities
in the northwest Bering Sea. According to the observations reported by
Zimmerman et al. (1977) in areas protected from ice scour, a typical
musse?/barnacle/filamentous red algae assemblage is evident; hydroids,
sponges, anemones, soft corals, bryozoans, green urchins, cucumbers,nudibranchs, limpets, gastropod, and tunicates round out this community.
Table C-2
SUBSTRATES OF THE LITTORAL ZONE FROM SHELDON’S POINT
(YUKON DELTA) TO CAPE PRINCE OF MALES
NORTON SOUND REGION
Type Kilometers (Mjles) Percentage
a
Bedrock 241 (149.5) 11.0
Boulder 389 (242.0) 18.0
Gravel 515 (320.0) 24.0
Sand 332 (206.0)
Mud 548 (340.5)
Not Categorized 87 (54.0) 4.0
Source: Zimmerman et al., 1977..
16.0
26.0
0
c-37
Oominant invertebrate predators are a starfish (Asterias SP.) and a
brachyuran crab (Telmessus sp.). In sandy areas polychaetes, clams, and
sand dollars are the dominant groups.
The marine community of rocky intertidal and shal?cw zones is better
developed around island perimeters despite similar ‘levels of ice scour.
Both sessile and midwater organisms are present in greater density and
diversity around King Island than at mainland sites (Zimmerman et al.,
1977) ● Presumably, greater circulation and access to nutrients held in
deep water is partly responsible for the enhanced productivity of islands.
Compared with rocky sublittoral communities of the southern Bering Sea
and Gulf of Alaska, there is a near absence of true kelp in the Norton
Sound region. Zimmerman et al. (1977) noted the, occurrence of Al aria at
Sledge Island and a diminutive stand of Laminaria-like algae at Bluff.
Rockweed (Fucus species) is the common “kelp” of this area. Shallow
water stands of eelgrass [Zostera) occur at several locations, notably
Port Clarence, Grantley Harbor, and Imuruk Basin (B~rton, 1978).
Results of a benthic
Jewett (1978). Samp”
130 feet) in depth.
southeast Bering Sea
biomass on the floor
survey of Norton Sound waters Mere reported by Feder and
es were trawled from waters of about 6 to 40 m (20 to
Unlike areas in the northeast Gulf of Alaska and
echinoderms, not crustaceans, dominate invertebrate
of Norton Sound: echinoderm biomass fractions observed
in these areas were 19.0, 17.5, and 80.3 percent, respectively (Feder and
Jewett, 1978). Invertebrate diversity patterns for Norton Sound are shown in
Figure C-12. hong the 187 species observed, dominiint groups included
mo??uscs (74 species), crustaceans (44 species), and echinoderms (27 spe-
cies). In terms of biomass these groups ranked in reverse: echinoderms,
mostly sea stars (80.3 percent), arthropods (9.6 percent), and molluscs (4.4 .
percent). Total epifaunal invertebrate biomass averaged 3.7g/m2 in the
Norton Sound region. Tanner crab, king crab, and shrimp are present in
Norton Sound, though not in sufficient quantities to support commercial
exploitation.
Sea stars and most other echinoderms are relatively long-lived and they
C-38
----
c-39
have evolved effective predator defenses. Thus, their huge biomass
reservoir is not directly a part of the food chain at higher trophic
levels in Norton Sound. Feder
portion of sea-star carbon is,
gamete production” (1978:433).
through planktivores to higher
and !Jewett speculate that “a considerable
in fact, returned to the sea annually as
Transfer of this portion is presumably
trophic levels. If this representation is
accurate, marine-based food chains, which ultimately lead to seals,
walruses, sea birds, whales, and man, may be particularly sensitive to
hydrocarbon pollution during seasonal peaks of sea star reproduction.
Fishes
Five species of salmon occur in the Norton Sound region. King, coho,
pink, and
exploited
The major
areshown
mouths.
chum salmon, in ascending order of importance, are commercially
and sockeye salmon are important in the subsistence fishery.
commercial fishing areas and salmon spawning/rearing streams
in Figure C-13. Most fishing is by gill net near stream
The commercial
first centered
pink, and coho
season runs from June 15 to September 30. Efforts are
on king salmon (to mid-July) and then shifted to chum,
salmon (Table C-3). Commercial processors terminate
operation in August.
Though the commercial salmon fishery of Norton Sound is a minor source
of income to the State as a whole, it is extremely important to the
local cash economy. In 1975, the total local income from 239,849 salmon
amounted to $437,000, and in nearly all areas the fishermen and process
workers are eskimos (McLean and Delaney, 1978a). Fishing cooperatives
have been organized in the Shaktoolik and Unalakleet districts and they
have stabilized fishing efforts in recent years. Part of the commercial
salmon catch is also utilized for subsistence purposes (see Section
11.3.3 below).
The sockeye population spawning in the Salmon Lake-Pilgrim River area
inland from Port Clarence is one of the northernmost populations of this
●
o
&o— —..z ---L
I
—. I
.-
/. . . . . ._+
$%g
\
9
9
TABLE C-3
PERIODS OF CONCENTRATIONS OF SALMON INSHALLOW WATER BAYS OF THE NORTON SOUND REGION
Species Period Available to Fishery
Chum June 20-25 to July 20-25
Pink June 25-July 1 to July 15-20
Coho August 1 to August 20
Source: McLean and Delaney, 1977.
,
C-42
species in the State. The sockeye fishery was closed to commercial
effort in 1974 but it is still heavily utilized for subsistence purposes
(McLean and Delaney, 1977).
Pacific herring support a growing commercial fishery and important
subsistence fishery in the Norton Sound region. In 1977, 9.5 metric
tons were produced at” Unalakleet and this figure is expected to increase
slowly as domestic fishermen gearup to replace yields garnered by the
Japanese fleet prior to passage of the Fishery Management and Conserva-
tion Act of 1976 (Barton, 1978; Wespestad, 1978).
At present, the commercial gill net fishery is directed toward extraction
of sac roe. Herring effort begins following break-up (late May to early
June) and lasts two to three weeks. Some subsistence fishing effort oc-
curs during fall (non-spawning) runs in Golovin Bay, Bluff, and Imuruk
Basin. Spawning has been observed near St. Michael, Klikitarik, Cape
t)enbigh, Elim, Golovin Bay, Bluff, and Imuruk Basin at intertidal or
shallow subtidal sites below exposed rocky headlands. Eggs are deposited
on rockweed kelp (Fucus) or bare rock. In the Port Clarence area, spawning
is in shallow brackish lagoons on eelgrass (Zostera) (Barton, 1978).——
Nearshore fish surveys have been recently conducled in Norton Sound.
More than 38 species in 15 families were collected by gill net, seine, or
trawl, of which nine species were freshwater, 10 were anadramous, and the
remainder were marine (Barton, 1978). Fish diversity patterns are shown
in Figure C-12. In general, Norton Sound appears to be less productive
for demersal fishes, both in diversity and abundance, than areas further
south and east in the Bering Sea, and the Chukchi Sea may produce compar-
atively greater quantities of Pacific herring (Pereyra and Wolotira, 1977;
Eiakkala and Smith, 1978). Among non-commercial fish sppcies, members of
seven families (clupeidue, osmeridae, gadidae, pleuronectidae, salmonidae,
coregonidae, and thymallidae) are used to some degree for subsistence by
local residents. These amount to 90 percent of the anadramous fishes, 75
percent of the freshwater fishes, and 30 percent of the marine fishes
occurring in the nearshore waters of Norton Sound (Barton, 1978). Other’
species (e.g., sand lances) are major forage for seabirds.
@
*
*
c-43 ●
Marine Mammals
Thirteen species of marine mammals are known to occur at least seasonally
in the lease sale area, including among pinnipeds, bearded, spotted,
ribbon, and ringed seals, and walrus; and among cetaceans, bowhead, fin,
gray, humpback, beluga, and killer whales, and harbor porpoises (Braham,
Fiscus, and Rugh, 1977). Polar bears are not abundant but they do occur
commonly in winter in the St. Lawrence Island area, having moved south of
the Bering Strait with the advancing ice. Since about 1975, polar bears
have become more abundant in the southern range, and closer to shore,
perhaps partly as a result of the cessation of aerial hunting in 1972(Klinkhart, 1977). Polar bears are taken by subsistence hunters each
year, though more often by natives of the Bering Strait and areas northward.
The important subsistence uses of marine mammals will be discussed in
11.3.3 below. The spatial distributions of marine mammal characteristics
in the sale
Figure C-14
Bearded sea”
area are shown for the months of March, April, and June in
s are strongly associated with driftirg ice and in late
winter to early spring most of the Bering-Arctic population is south of
the Bering Strait. They seldom use shore-fast ice. In spring they
follow the receding pack ice northward though some individuals remain
throughout the summer in Norton Sound and around St. Lawrence Island
(Lowryet al., 1978). Bearded seals, less social than other species, do
not herd and are likely to be found singly (Burns and Frost, 1979). They
feed primarily on spider and tanner crabs, and to a lesser extent on
fishes, clams, and hermit and king crabs (Lowry et al., 1978).
The spotted or largha seal (as separate from the harbor seal following
the distinction of Braham, Fiscus, and Ru~h, 1977) utilize the ice front
in the Bering Sea for whelping and molting in late winter and early
spring. They may follow the ice northward but often take up residence in
both mainland and island coastal waters. In summer and fall they are
found along the entire coast of northern Alaska (Kl inkhart, 1977). They
prey primarily on fish (Lowry et al., 1978).
c-44
“Ezzz! March (Bearded Seal, Walrus)
r-l June (Pinnipeds)(Bearded Seal, Spotted0° :“ “ Seal, Ringed Seal, Walrus) ~;;g~: .
El June (Gray Whales)
A Bowhead & Beluga Whale L:: -i
-- .-+ u au lUU Iau——
Figure C–a 4
APPROXIMATE EXTENT OF MAJOR MARINE MAMMAL CONCENTRATIONS IN THE LEASE AREA
* o●
[Based on observations reported by Braham. Fiscus and Rugh, fikl?7)
● 9 e P @ a a ●☛
9
Ribbon seals are similar to spotted seals in their use of the pack-ice
front in winter and early spring for whelping and molting. Unlike
spotted seals, ribbon seals take up a pelagic habit in summer, where they
prey mostly on fishes (gadids) and pandalid shrimp (Klinkhart, 1977;
Lowry et al., 1978).
Ringed seals are widely distributed in the Bering and Chukchi Seas
across areas of land-fast ice, where breeding takes place in spring.
Though most adults migrate northward, juveniles
Sound. Their diet is varied. Stomach samples,
reflect local prey availability, have contained
shrimp, cods, sculpins, and other fishes (Lowry
1977).
Walruses migrate seasonally with the ice front.
may summer in Norton
which may strongly
zooplankton, pandalid
etal., 1978; Klinkhart,
Herds are absent from
the lease sale area only in July and August, i.e., when the last of the
drifting broken ice has receded north of the Bering Strait. Peak abun-
dances are from January through June in the sale area. Areal abundance
is centered on St. Lawrence Island in winter and the population moves
directly northward in summer, appearing, for the most part, to avoid the
waters of Norton Sound (Burns, Shapiro, and Fay, 1’377).
Less is known of the distribution and-seasonal migrations of whales in
the lease sale area. llowhead whales are an endangered and controversial
species highly prized by natives of the Bering Strait and areas northward,
and also to a lesser extent by St. Lawrence Islanders (Arctic Environmental
Information & Data Center, 1979). They pass through the Bering Straitfrom March to June, and return again before freeze-up in fall. Their ap-
proximate travel routes follow ice leads in the spring around St. Lawrence
Island (Figure C-14; H. Braham, personal communication).
Gray whales, also endangered, are found from the St. Lawrence area north
to the Bering Strait in June (Figure C-14). In August and September,
they feed in the inshore waters of Siberia and Alaska, and over the
continental shelf. In the fall they return through the Bering Strait in
a southward migration (Braham, Ficus, and Rugh, 1977).
C-46
Beluga (belukha, or white) whales are found year round in the lease sale
area. They are known to ascend rivers and to concentrate in shallow
estuarine and coastal areas. They feed on smelt or salmon (Klinkhart,
1977). “
Information on the temporal occurrences of marine mammals in Norton Sound
is summarized in Table C-4.
11.3.3 Subsistence and Sport Hunting and Fishing
Natives of the lease sale area used a wide variety of logical biological
resorces for subsistence. Year-to-year climatic and geographic variations
in the relative harvest levels of important species and sparse published
m a t e r i a l m a k e p a t t e r n s o f u t i l i z a t i o n d i f f i c u l t t o c h a r a c t e r i z e . I n evalu-
(~j ( i . e . , u n p r e d i c t a b l e )sting the impacts of OCS development, non-secular
changes in demands on subsistence resources which result from government
economic support, replacement of sled dogs by snow machines, participation
in the ?oca? cash economy, and a rekindled awarnesss of the cultural benefits
of subsistence hunting must be considered.
/hong terrestrial species moose, black bear, red Fox, arctic fox, mink,
land otter, beaver, snowshoe and tundra hare, willow and rock ptarmigan, and
spruce grouse are important to the dietary, garmel~t, and cash-exchange needs
of natives. Other species, e.g., muskrats, are used on an incidental basis(KI inkhart, 1977).
Waterfowl and seabirds are also important contributors to the diets of
natives. Canada, white-fronted, brant, emperor, and snow geese are heavily
utilized, as are a variety of ducks. Eggs of ducks, geese, and a variety
of cliff-nesting seabirds supplement summer diets, especially for natives
on St. Lawrence Island (Burgess, 1974).
(~) The use of the term non-secular is used to convey the idea that certainevents occur in a manner that does not assist in predicting the next eventi.e., the events are not really linked to each other.
*
e
●oc-47
TABLE C-4
I
SUMMARY OF TEMPORAL USE OF THE NORTON SOUND LEASE SALE AREABY PINNIPEDS AND CETACEANS
Area Uses*Species Migration Reproduction Feeding
Bearded seal w S!J Sp Y
Spotted (largha) seal w Sp Su F
Ribbon seal Su Su F
Ringed seal W Sp Y
Nal rus M Sp Sp w Sp
Bowhead whale Sp
Fin whale Su F s
Gray whale Sp F Sp Su
Humpback whale Su Su
Beluga whale Y
Harbor propoise + +
Killer whale Su F Su
Source: Braham, Fiscus, and Rugh, 1977.
* Key to entries: Y =w=Sp =
Su =
F ===
Bla;k =
year roundJanuary-MarchApril-JuneJuly-SeptemberOctober-Oecemberbehavior is not noted for this areabehavior is known to occur but details are unknowngaps in information
C-48
Subsistence use of fishes varies among natives
Villagers along the ease coast of Norton Sound
of the lease sale region.
and Seward Peninsula outilize salmon, and to the lesser extent, herring. Part of the commerical @
salmon catch, diverted to local use, supplements the subsistence harvest.
Chum and pink salmon are by far the most importart subsistence species.
The once important sockeye fishery in the Port Clarence area appears to
‘be failing, though it has been closed to all but subsistence effort
(McLean and Delaney, 1977).
The reliance on salmon declines and importance of herring increases
greatly for villagers of St. Michael and the Yukon Delta region, who
utilize the preserved summer catches of adult herring and kelp roe for a
year-round food supply (Dames & Moore, 1978b). Other important subsistence
fishes of the sale area include whitefishes, northern pike, burbot,
sheefish, ciscos, saffron cod, and smelt (McLean and Delaney, 1977).
Among marine mammals, all of the four seal species, walrus, bowhead
whale, and polar bear are hunted for meat, oil, skins, and ivory. Ringed
seals account for more than haJf the annual seal harvest (Klinkhart,
1977) . Villagers of the offshore islands and Bering Strait are the most
avid hunters, though seal products are so valued that hunters from un-
favorably located villages, e.g., on the Yukon Delta, travel at great
expense and risk to hunt them (Dames & Moore, 197:3c). Bowhead whales are
hunted by St. Lawrence Islanders and natives of the Bering Strait.
Gray whales are not taken to any great extent by :;ub~istence users.
●
Q
Other marine species contribute incidentally to the diet of nativesincluding clams, tanner and king crabs, and shrimp (Alaska Dept. Fish &
Game, 1978). Eelgrass p?ays an important subsistence role in its usein food preservation and storage (Dames & Moore, 1978c).
●
Virtually all of the species utilized by natives for subsistence purposes
also support sport recreational activities. Moose, wolves, wolverine,
grizzly bear, beaver, king salmon, silver salmon, and arctic char are●o
c-49
.-
9
among species that appear to be more actively pursued by non-native
sportsmen and trappers than by eskimos of the sale area. With the
increased price offered for lynx pelts in recent years, this species has
become sought after by commercial trappers (KI inkhart, 1977). Sp{
hunting for walruses is no longer allowed by permit following the
1979 return of regulatory jurisdiction to the federal government.
hunting had provided a cash income for eskimos who served as hunt
guides (KI irtkhart, 1977).
rt
July 1,
Sport
ng
11.3.4 Biological Constraints on OCS Petroleum Development
The development of petroleum resources in the Norton Sound area will
unavoidably perturb local marine and coastal populations. Non-catastrophic
impacts will arise from the direct effects of vessel traffic, aircraft
noise, exploratory and construction activity, and loss of habitat to
platforms or other facilities; indirect effects accrue from chronic
low-level pollution near terminal facilities. These foreseeable impactsI
may be solved somewhat in early stages by imposing constraints on develop-
ment in sensitive areas of the Norton Sound region. Avoiding catastrophic
impacts, e.g., from a major crude oil spill, is more difficult to accomplish
through the planning process.
The vagaries of biological systems are most easily accommodated by de-
fining discrete time periods or critical geographic areas.
Sound region, two sensitive time periods clearly stand out:
(1) Early spring, when reduction of open water by”ice
For the Norton
cover is
likely to force vessel traffic, sea birds, and marine mammals
into close contact. Intolerance of vessel or aircraft noise
may precipitate their avoidance of traffic lanes but in early
spring when ice leads are heavily utilized, escape may not be
possible: seals are likely to be struck by ships from Aprilthrough June though mortality will be small (Burns and Frost,
1979). Constraints on use of their migratory lanes by
vessels may be applied.
C-50
(2) Spring to early summer, when reproduction by marine species
at all trophic levels initiates a period of accelerated growth
in regional productivity. Eggs and larvae of herring, as do
those of many other marine fishes and invertebrates, suffer
high levels of mortality when exposed to petroleum hydrocarbons
(Rice, Kern, and Karinen, 1978; Lowry et al., 1978). High risk
operations may be curtailed during this period.
Dense aggregations of individuals are particularly vulnerable to direct
disruptionor pollution, and sites where aggregations dependably occur
may be protected from development. Other bases for designation of
critical geographic areas include centers of biotic diversity, sites of
legislated state or federal protection, areas of productivity for commercial
or subsistence species, and locations of critical habitat. Such sites
for species in the sa?e area have been discussed in preceding sections of
this report. A summary is provided in Table C-5.
Certain general features of exploration for and development of petroleum
resources in Norton Sound need not reference specific locations or petro-
leum reserve levels for identification of their associated constraints
and impacts. A brief evaluation of specific environmental considerations
follows each of the scenarios; here it is noted that a petroleum find at
any exploitable level would require:
Q Vessel and aircraft support. The choice of traffic routes and
schedules may be constrained by stipulations which protect
marine mammals, migratory waterfowl and seabirds. Though
walrus, seal, and whale migratory routes generally fall west of
Norton Sound, the expansion of activities into the ice-bound
months may enhance the potential for conflict. They may avoid
summer vessel routes, but learn to frequent leads artifical?y
maintained by ice-breakers. Conversely, seismic explosions
during OCS exploratory phases are likely to promptw holesale
abandonment of nearby areas. Aircraft should also be routed
away from known nesting areas of waterfowl and seabirds.
Despite these precautions, increased noise from vessel and
a i r c r a f t m a y s t i l l h a v e a n e g a t i v e i m p a c t o n m a r i n e m a m m a l a n d
b i r d p o p u l a t i o n s .
●
●
C-51 ●
I
TAllLE C-5
SUMMARY OF LOCATIONS SENSITIVE TO DISRUPTION BY OCS PETROLEUM DEVELOPMENT Activities
Area Basis for Selection Reference
Y u k o n Oelta and Adjoining F e d e r a l l y p r o t e c t e d a s a n a t i o n a l F i g u r e C - nc o a s t a l z o n e w i l d l i f e r a n g e ; c r i t i c a l h a b i t a t
for fish and waterfowl production
Salmon fishing zones Critical cash base for local Figure C-13economy
Salmon spawning streams Critical habitat for commercial Figure C-13species
Herring spawning zones Critical habitat for subsistence text; alsoresource Barton (1978)
Zones of invertebrate and Important in the maintenance of Figure C-12fish diversity local ecosystem quality as a
source of propagules to renewdisturbed areas
Bering Land Bridge Critical migratory bird and text; alsoNational Park waterfowl habitat; proposed Klinkhart (1977)
for federal protection
Little Oiomede Sledge, King and Seabird colonies of high Figure C-IIEgg Islands, Fairway Rock, diversity; many proposed forRluff, Cape Denbigh, Square” federal protectionRock, and Cape Darby
Southwest Cape, Sevoukok Seabird colonies of high Figure C-11Mountain, and Cape Myangee densityin St. Lawrence Island
Unalakleet River Valley Critical moose habitat Figure C-11
Offshore region north and March and April only: concen- Figure C-14west of St. Lawrence Island trations of marine mammals
Bering Strait, north and June only: concentrate ions Figure C-14south of Little Diomede Island of marine mammals
C-52
●
o Gravel islands. Information contained in a review of potential
impacts of artificial islands in the southern Beaufort Sea (Canada o
Department of the Environment, 1977) is partly relevant
Sound. The process of construction of grave? islands w
affect local populations though direct mortality during
fill operations and by creation of turbidity plumes. T
to Norton *
11 chiefly
dredge and
ming and
location may be critical: increased inshore turbidity may adverse- @
ly affect aggregating salmon and herring during spawning runs and
may interfere with the early development of herring larvae. Direct
localized mortality during construction may be important if borrow
or fill sites coincide with points-of high benthic.p roductivity or
invertebrate diversity. Post-construction effects include long-
term changes in local communities induced by the addition or loss of
habitat. Local fish resources and bentttic diversity may be en
hanced by the addition of vertical relief in habitat. In winter, if 9polynyi should form around gravel islands, they may attract
overwintering seals. Finally, abandonment of gravel islands, ‘
without adequate precautions, may result in hazards to navigation.
e Onshore and offshore pipelines. Placement of offshore pipelines
may be constrained by the location of c~mmerciaJ or subsistence
fishing areas, which are inflexible in location and of high
overall economic value. Offshore route; should also be considered
which minimize harm from potential spills. Onshore pipelines
paralleling the coastline bear enormous potential impact on
fish populations, especially salmon. The economic importance
of the salmon fishery requires that pipelines be constructed at
stream crossings to allow unimpeded passage of migrating fish,
and without disturbance of spawning and rearing areas. llse ofnon-fish stream gravel resources for construction will be a
Iike?y stipulation. Construction and maintenance costs relative eto these restrictions may prove so high as to recommend substitu-
tion of offshore pipelines for onshore routes wherever possible.
9 Compliance with state and federal regulations. The Alaska OCS ●
Environmental Assessment Program has produced new information o
c-539
on lease-sale areas which will become the basis for environmental
stipulations and regulations on petroleum exploitation.
Results of lease-sale negotiations in progress for the Beaufort
Sea may forecast the future of other sale areas. Important
points of discussion include length of the permissible drilling
period, types of offshore exploratory platforms, disposal of
temporary facilities, vessel/aircraft routes, and spill/blowout
contingencies. A review of the existing regulations governing
OCS petroleum development fol
11.3.5 Environmental Regulations
1 Ows .
The U.S. Department of Interior, as administrator of outer continental
shelf mineral resources, is mandated to protect marine and coastal
environments via a number of legislative acts including: NationalEnvironmental Policy Act of 1969, Coastal Zone Management Act of 1972,
Estuary Protection Act of 1973, Fish and Wildlife Coordination Act, and
others. These various acts require that environmental impact be consid-
ered in the planning and the decision-making process relating to develop-
ment of petroleum resources. Therefore, a coordinated industrial-govern-
mental multidisciplinary effort will be involved iq the evaluation of any
proposed development activity. In addition to the general planning
requirements, specific regulations” relating to offshore procedures are
presented in the Outer Continental Shelf Lands Act (as amended in
September, 1978), titles 30 and 43 of the Code of Federal Regulations,
U.S.G.S. OCS operating orders, stipulations required to mitigate impacts,
and the Environmental Protection Agency regulations pertaining to offshore
oil and gas extraction. Some of the specific environmental regulations
that could affect the course of development by restricting activities or
making certain procedures impractical include:
9 EPA discharge standards for production waters and other
by-products of the drilling operation will affect the design of
facilities and may affect the practicality of procedures such
as offshore loading of oil.
o Stipulations require that areas of historical or archeo’
importance be protected.
c-54
ogical
e Stipulations require that facilities (including pipelines)
not interfere with commercial fishing, marine mammals, or bird
rookeries.
Federal regulations governing OCS activities are Incomplete and in the
process of evolution. The forthcoming OCS Orders for the Bering Sea
(which wil 1 include the Norton Sound lease sale area) wil 1 probably be .
sim~lar to those for the Gulf of Alaska (R. Smith: U.S. Geological
Survey, personal communication). Furthermore, the controversy over
federal lands withdrawn under the Federal Land Policy Management Act has
yet to be decided. Thirteen locations, in or adjcining the lease sale
area, may become part of the national wildlife refuge system.
In addition to those regulations that pertain specifically to OCS petro-leum development, there are numerous general regulations and permit
requirements that may apply to various aspects of onshore and offshore
development. These are listed on Table C-6.
11.4 Gravel Resources
11.4.1 Introduction
A description of the gravel resources of the Norton Sound area is
relevant in this report because the construction of petroleum facilities
both onshore and offshore requires large quantities of gravel. Onshore
construction in permafrost terrain necessitates significant quantities of
gravel for foundation pads, roads, air strips, wori pads, pipeline
bedding, etc., while offshore gravel may be required for construction of
artificial islands as drilling platforms or loading facilities. A
summary of gravel requirements for various petroleum facilities is given
in Table C-7.
A gravel resource can be classified as an accumulation of gravel of
sufficient quantity which can be economically utilized. Inherent in the
classification are the cost considerations of:
(1) Burial depth of the resource and stripping ratio of overburden
to gravel.
9
9
●oC-55 ●
—
TAEfLE C-6
PERMITS AND REGULATIONS CONCERNING PETROLEU!4 OEVELOPNENT
ffiENCY PERllIT/ACTIVITY AUTHOR I TY— .
Department of Fish & Game
Department of EnvironmentalConservation
STATE OF ALASKADepartment of Natural Resources Oil and Gas Leases
Pipeline Rights-of-MayGravel Pennits and SalesWater Use Permits
Water Use PermitsHydraulic Penni tsAuthority to Remove Nuisance Wildlife
Water Quality StandardsBallast Mater Discharge PennitSurface Oiling PermitSolid Waste Management PermitAir Quality StandardsBurning Permit
FEDERAL GOVERNMENTArmy Corps of Engineers
U.S. Coast Guard
8ureau of Land Management
Permit to Work in Navigable Maters
Permit to Discharge into Nav. Waters
Bridge Permits-Navigable Waters
Protection of Critical HabitatSpecial Use Permits:
Gravel Mini ngConstruction CampsTimber DisposalCommunication Sites & Right-of-WayConstruction Disposal AreasGravel Oisposal
Airport LeasesOi 1 and Gas LeasesRight-of-Way Permit2Off-Road-Vehicle Permits
Environmental Protection Agency Wastewater Discharge PermitOil Pollution PreventionControl Oil Spill Clean-up
Fish & Wildlife Service Protection of Fish, Wildlife & HabitatOuter Continental Shelf DevelopmentEstuary ProtectionSpecial Use Pennits -- Wildlife
Ranges and RefugesMarine Marona\ ProtectionEndangered Species ProtectionEagle ProtectionWaterfowl Protection
National Marine Fishery Service Protection of Anadromous Fish HabitatMarine Mannial ProtectionOuter Cent i nental Shelf Development
Department of Transportation Pipe]ine Safety & Valve Locationsat Stream Crossings
Source: Dames & Moore
Alaska Statute 38.05.180Alaska Right-of-Way Leasing ActAlaska Statute 38.05Alaska Water Use Act; Alaska Statute 46.15.010
Fish & Game Act of 1959; Alaska Statute 16.05.870Fish 8 Game Act of 1959; Alaska Statute 16.05.870Fish & Game Act of 1959; Alaska Statute 16.05.870
Alaska Water fjual ity Standords 1973Alaska Statute 46.03.750Alaska Statute 46.03.050Alaska Statute 46.03.050Alaska Statute 46.03.050Alaska Statute 46.03.050
Refuse Act; Rivers & Harbors Act 1899, Title 33 CodeRegulations Part 209Water Quality Improvement Act 1972; Title 33 Code ofPart 209
Title 33 Code of Federal Regulations Part 114
Federal Land Pol icy Management Act 1976
Title 43 Code of Federal Regulations, Part 2920Title 43 Code of Federal Regulations, Part 2920Title 43 Code of Federal Regulations, Part 5400Title 43 Code of Federal Regulations, Part 2920Title 43 Code of Federal Regulations, Part 2920Title 43 Code of Federal Regulations, Part 3610Title 43 Code of Federal Regulations, Part 2911Mineral Leasing Act of 1920 and RevisionsFeder~l Land Policy and hianagement Act 1976Sikes Act
Water Pollution Control Act 1972Water Pollution Control Act 1972Water Pollution Control Act 1912
Fish 8 Wildlife Coordination Act 1973Fish & Wildlife Coordination Act 1973Estuarine Study Act of 1968Title 50 Code of Federal Regulations
of Federal
Federal Regulatius
Marine Mamnal Protection Act i972 (Polar 8ear, Ualrus, Sea Otter)Endangered Species Act 1973Eagle Act of 1972kiigratory Bird Treaty Act
Fish & Wildlife Coordination Act 1973Marine Manonal Protection Act 1972 (Whales and Seals)Fish & Wildlife Coordination Act 1973
Title 49 Code of Federal Regulations, f’art 195
r)
A-4
●
TARLE C-7
SUMMARY OF GRAVEL REQUIREMENTS FOR VAR1OUS PETROLEUM FACILITIES IN ARCTIC A!iO SUBARCTIC REG1ONS
FacilityGravel Requirements
Dimensions/Specifications cubic meters cubic yards Comnents
Pipeline work pad 1.5 meters (5 feet) thick; 20 meters 30,177/km(65 feet) wide
63,555/mile Typical Alyeska dimensionsfor above ground pipe;
Pipeline access road 1.5 meters (5 feet) thick; 8.5 meters 10,214/kmscenario work pads may be
21,511/mile(22 feet) wide
somewhat narrower sincepipelines are smaller
Pipeline haul road 1.5 meters (5 feet) thick; 9 meters 13 ,92B/km(30 feet) wide
29,333/mile
Airstri~ (ail weather] 1,523 x 40 meters (5,000 x 150 feet); 84,955- 126,159 110,000 - 165,0001.2to 1.8 meters (4 to 6 feet) thick
Camp and dri 11 pad 128 x98 meters (420 x 320 feet), 26,760- 38,230 35,000- 50,000(onshore exploratory wel 1 ) 1.27 hectares (3.1 acres)
Crude Oil Terminal
Smal 1 -Medium (<250,000 b/d) 32 hectares (80 acres) 267,610 - 535,220 350,000 - 700,000
Large (500,000 b/d) 120 hectares (300 acres) 1,146,900- 1,911,500 1,500,000- 2,500,000
Very Large (>1 ,000,000 b/d) 202 hectares (500 acres ) 1,835,040 - 3,440,700 2,400,000 - 4,500,000—
LNG Plant
Smal l-Medium (400 MMCFD) 25 hectares (60 acres) 214,088 - 420,530 280,000 - 550,000
Large ( 750-1,000 MMCFO) 100 hectares (250 ‘acres) 917,520 - 1,529,200 1,200,000- 2,000.000
Construction Support Base 16 - 30 hectares (40 - 75 acres) 152,920 - 382,300 200,000 - 500,000
Exploration Island see Table C-12
Production Island see Table C-12
Source: Dames & Moore estimates.
● 9 Q ● ●
(2) Preparation and/orbenefication of the gravel.
(3) Handling and transportation of the gravel to where it is being
utilized.
Many large concentrations of gravel may not be “resources” as the mining
and/or handling and transportation may be prohibitively expensive.
The development of gravel accumulations is dependent upon two conditions:
(1) there must be a source area, such as pre-existipg rock or formations/
deposits containing grave?, from which gravel may be derived; and (2) there
must be some gravel concentration mechanism. In Arctic areas gravels are
commonly derived from pre-existing rock or from formations/deposits con-
taining gravels by alluvial and/or glacial processes. The derived gravel
may be later concentrated in river channels or along beaches as current
and/or wave sorting acts to segretate out and remove the finer fractions
of sediments.
11.4.2 Distribution of Gravel Resources in Norton Sound
In the Norton Sound there are three general areas where gravel resources
may be present. These areas are:
(1) The
(2) The
(3) The
onshore coastal plain adjacent to Nome.
offshore areas immediately south of Nome.
offshore area north of St. Lawrence Island.
The gravels in the areas are probably glacial related. Outside these
areas onshore and offshore gravel potential is probably poor because:
(1) Density of gravel deposits is probably low (onshore and offshore).
(2) The gravel accumulations are overlain by thick deposits of finergrained sediment (onshore and offshore).
C-58
. .
{3) The gravel areas in a permafrost zone would require considerable
thawing time before they could be mined (onshore).
Each of the potential gravel areas identified above is discussed below
and possible gravel deposits within these areas are identified and
evaluated. Figure C-15 shows the distribution of surface sediments in
the northern Bering
11.4.2.1
Many buried beaches
Sea including percentage of gravel in those sediments.
Coastal Plain at Nome
are present along the coastal plain of Nome. The -
beaches, some buried to a depth approaching 33 meters (99 feet), are
linear features containing goldbearing gravels. Currently the Alaska
Gold Company is mining a number of these buried beaches. The tailings
from the mining operation are being stockpiled in large piles, some over
15 meters (50 feet) in height. The material in the stockpiles is domi-
nated by coarse sand through coarse gravel sized material but contains
fines, cobbles, and boulders. The State Highway Department of Alaska is
purchasing some of the tai<
the Nome area.
Many buried beaches remain
ing for maintaining and upgrading of roads in
.
to be mined along the coastal plain. In the
present state, these buried beaches are in the permafrost zone and are
frozen. A period of up to three summers of processing time, generally
by circulating water through the gravel deposits, is required before one
summer’s worth of to-be-dredged gravel is
11.4.2.2 Offshore Zone at Nome
thawed.
The offshore zone at Nome contains a complex of relict deposits most
recognizable by bathymetric expression and/or geophysical characteristics.
Some of the features include glacial drift deposits, buried alluvial
channels, beach ridges, and outwash fans (Tag and Greene, 1973).
Glacial drift deposits blanket large areas of the coastal plain and
offshore zone at Nome. The material is dominated by sand, gravel, and
●
●
m
*
●e
c-59 ●
[;. ” I 70. :.5.4. ] ,6,.
CHUKOTKA }:.P E N I N S U L A
SEWARDPEN IN SUL4
f “’”n” )T,d { jzg”,.
Tookok ,,:-.. fl. .H-ad - -- - - - — - _ — _
“LAND Jh./-~~lS T L4WRENCE
oL . - . —
2 50 kilometers1 1
-.. _ -—- __ ---———---- — --—_--—___ - a-_—_-_” -_ _ _ )-— - - ——-.- —__ ___ . . .-——- - — _ _ _, y .:.:.:-:j~- - - - - ____, - - - - - - ---—_ —___— ., .--,
, —- –——————-—- .Q,---
,-———. ..
EXPLANATION
Onm>0-m 1 (J-XI m I
Percentage of gravel in surfxe sediments
Fine silty sfimi
cl.-—--—.----—Yukon silts
Figure C-15
DISTRIBUTION OF SEDIMENTS IN THE NORTHERN BERING SEA
(Distribution of Yukon silts and clay modified fromMcManus and others, 1969) Source: Nelson and Hopkins, 1972
glacial till but contains cobbles and boulders. The glacial drift
deposits contain gold; however, the gold is generally not concentrated
enough to make the deposits a target for gold mining.
Beach and alluvjal processes acting upon the glacial drift can concen-
trate gravels. Beach ridges, outwash fan, and tiuried channels in the
Nome offshore area are features in which gravels are concentrated. Many
of the relict beach and alluvial deposit offshore of Nome show bathy-
metric expression. The linear submerged beach yidges contain concen-
trations of gold-bearing gravels. Generally, only the gravels occur as
a thin veneer and consequently the volumes of gravel are not that large.
Outwash fans from developed glacial deposits contain appreciable quanti-
ties of gravel. These deposits are both laterally extensive and thick
(approximately 5 meters [18 feet]). The predominant material in the
outwash fans is
boulders.
Buried channels
probably sands and gravel with some fines and cobble and
are subbottom features which can be delineated on geo-
physical records. Approximately 20 buried channels or depressions have
been recognized in the Nome offshore area (Tagg and Greene, 1973). Some
of the channels are shallow while others are buried beneath a consider-
able thickness of sediment. The channels are trough-like in form and
contain some gravels as indicated by their acoustical signal. The
proportion of gravels in the buried channels and their lateral extent
and thickness is not known.
11.4.2.3 North of St. Lawrence Island
During the Pleistocene, Siberian glaciers advanced beyond the present-
day shore?inee north of St. Lawrence Island. Glacial drift deposits have
been recognized in this area. Although no detailed geophysical work has
been done to de?imit relicit deposits, it is likely that relicit deposits
similar to those offshore of Nome are present in the St. Lawrence Island
area.
m
●o
C - 6 1 ●
11.4.3 Availability of Gravel for Offshore Gravel Islands
Onshore sources of gravel are available from the tailing piles at the
placer gold mining operation currently underway in F!ome. The volume
of gravel available can be easily determined; however, the price per
cubic yard of gravel remains to be negotiated. The cost of transferring
this gravel to an offshore site is undoubtedly great as the gravel will
require at least two handlings including an onshore to offshore transfer
system. Furthermore, it is likely that shallow draft barges will be
used to transport the gravel from Nome to an offshore location as the
waters around Nome are shallow. The lower volume
will add additional inefficiencies to the onshore
tation cost.
shallow draft barges
to offshore transpor-
The gravel accumulations offshore of Nome which are contained in out-
wash fans, buried channels, and beach ridges offer another possible
source of gravel.
(1) They are
(2) They are
(3) They can
These deposits have the following attributes:
probably free of permafrost.
surface or nearsur~ace deposits.
be easily mined by conventional offshore mining
techniques.
(4) They would require minimal handling.
There may he competing interests for these offshore gravel accumulations
as they contain placer gold and they are considered target areas.
Of the three offshore gravel deposits described above, the gravel accumu-
lations in outwash fans represent probably the best potential gravel
resource. The fans are laterally extensive fairly thick and probably
contain appreciable quantities of gravel. The buried channels and
beach ridges are linear features which undoubtedly contain lower volumes
of gravel.
C-62
Gravel deposits similar to those offshore of Nome probably exist adjacent
to the north side of St. Lawrence Island; however, many of the deposits
remain to be verified. At the time these gravel deposits are verified,
they can be evaluated as a potential gravel resource.
11.4.4 Conclusions
The two best potential gravel resources for grzvel island construction
are: (1) the onshore tailing piles at Nome, ard (2) the gravel accumu-
lations in the outwash fans offshore of Nome. Much is known or can be
determined concerning the composition and volumes of the gravel contained
in the
tation
accumu”
handle
in the
tailing piles; however, the cost of the gravel and the transpor-
costs to an offshore site have not been worked out. The gravel
tions in the outwash fans are undoubtedly less costly to recover,
and transport; however, the composition and volume of gravels
deposit are not yet known. Until these unknowns are resolved and
costing studies are made, it is not possible to make a determination as
to whether or not these gravel accumulations constitute a developable
gravel resource.
11.5 Water Resources
11.5.1 Water Resources Inventory
11.5.1.1 Surface Water
Surface water resources in the Norton Sound ared include several river
systems and many small streams. River systems include the Kuzitrin,
Unalakleet, Inglutalik, Niukluk, Fish, and Agiapuk. Table C-8 lists
and describes these rivers and many of the small streams in the area.
a9
●
●Surface runoff in this region is highly variable due to the lack ofprecipitation, the presence of permafrost, and the numerous low mountains.
Mean annual runoff is estimated at 1.1 cubic meters/minute
kilometer (1 cfs per square mile), with figures as high as
meters/minute per square kilometer (2 cfs per square mile)
per square
2.1 cubic●
in some areas.o
C-63 ●
TABLE c-8
INVENTORY OF SURFACE WATERS IN THE NORTON SOUND AREA
Estimated Important toDrainage Area Average Annual Flow Anadromous
Name Tributary to sq. km. sq. mi. cu. m./min. (Cfs ) Fish
Unalakleet Norton Sound 5,387 2,080 3,398 2,000 Yes
South Unalakleet R 1,290 498 816 480 Yes
North Unalakleet R 321 i24 204 120 YesChiroskey Unalakleet R 803 310 510 300 Yes
Old Woman Unalakleet R 793 306 500 294 Yes
Ulukuk Unalakleet R 606 234 367 216 No
Shaktolik Norton Sound 2,214 855 1,597 940 Yes
Ungalik Norton Bay 1,792 692 1,291 760 Yes
Inglutalik Norton Bay 2,598 1,003 1,920 1,130 Yes
Akul ik Norton Bay 78 30 56 33 NoKoyuk Norton 8ay 5,097 1,968 3,679 2’,165 Yes
East Fork Koyul( 860 332 622 366 No
Peace R Koyuk 552 213 398 234 YesMukluktulik Norton Bay 104 40 75 44 Yes
Miniatulik Norton Bay 47 18 34 20 No
Kuiuktulik Norton Bay 47 18 34 20 No
Kwi k Norton Bay 531 205 382 225 Yes
Tubutulik Norton f?ay 1,044 403 1,014 597 YesKwiniuk Norton Bay 5,672 219 552 325 Yes
Youngl ik Norton Sound 150 58 102 60 NoI Niukluk Norton Sound 5,670 2,189 3,823 2,250 Yes
Fox Niukluk 192 74 129 76 No
Fish Niukluk 3,069 1,185 2,073 1,220 Yes
Pargon Fish River 363 140 245 144 No
Etchepuk Fish River 549 212 370 218 Yes
Rathlatulik Fish River 192 74 129 76 No
8ear Niukluk 101 39 68 40 No
Casadepaga Niukltik 601 232 408 240 Yes
Libby Niukluk 409 158 277, 163 No
Klokerblok Norton Sound 469 181 234 138 Yes
Skookum Klokerblok 65 25 32 19 No
Topkok Norton Sound 65 25 39 23 NoSolomon Norton Sound 352 136 251 148 YesBonanza Norton Sound 321 124 263 155 YesEldorado Norton Sound 655 253 537 316 YesFlambeau Eldorado 218 84 178 105 YesNome Norton Sound 420 162 391 230 YesSnake Norton Sound 334 129 311 183 YesPenny Norton Sound 88 34 82 48 YesSinuk Bering Strait 803 310 748 , 440 Yes
Stewart Sinuk R 148 57 144 85 NoFeather Bering Sea 189 73 107 63 YesTisuk Rering Sea 207 80 136 80 No
Bluestone Bering Sea 300 116 144 85 YesCobblestone Bering Sea 189 73 93 55 Yes
I
C-64
TABLE C-8 (Cent. ) e*Name-.—. — .—... -—-
Kuzitrin
Kruzgamepa
Grand Central
Kaviruk
KougarokNoxapagaAgi apukAmericanCal iforni aDon
Lost
Rapid
King
Kanauyuk
Anikovik
Mint
Yankee
Tributary to ,,
i3ering SeaKuzitrinKruzgamepaKuzitrinKuzitrinKuzitrihBering SeaAgi apuk
Bering Sea
Bering Sea
Bering Sea
Lost River
Bering Sea
Bering Sea
Bering Sea
Chukchi Sea
Mint River
Draif——.—.-u
6,734
1,259
135
580
1,453
1,238
2,896
1,569
161
287
85
41
28
65
78
414
75
e Area—z_~. n i l .
2,600
486
52
224
561
478
1,118
606
62
1113316112530
16029
EstimatedAverage Anr
‘c~. m.lmin. . _—_:
3,254
909
195
280
705
544
1,538
833
92
161
48
24
14
31
37
187
34
Source: U.S. Geological Survey, !4at.er Data Reports (various years)
al rl~w7cf s-)-
1,915
535
115
165
415
320
905
490
54
95
28
14
8
18
21
110
20
~ortant tcAnadromous
Fish -—
YesNoYesNoNoNoYesYesNoNoNoNo
No
No
No
No
No
*
●
●
*
C-65
Mean annual peak runoff ranges from 10.5 to 26 cubic meters/minute per
square kilometer (10 to 25 cfs per square mile), being generally lower
in the southern portion of the area. Peak flows typically occur in May
through August with minimum flows 0.21 to zero cubic meters/minute per
square kilometer (0.2 to zero cfs per square mile) occurring rom December
through March.
Though area-wide estimates have been made, little data is available for
specific streams. The U.S. Geological Survey is )resently monitoring six
sites in the area, all of which are located near Flome. Table C-9 shows
some of these results.
Average annual surface runoff from the entire area is estimated at
approximately 39,082 cubic meters/minute (23,000 cfs) annually or about
57 liters (15 million gallons) per day. F?aximums minimums vary from
almost 114 liters (30 million gallons) per day to 5.7 million liters (1.5
million gallons) per day respectively.
The chemical quality of the surface water in the ,~rea is generally good
and is acceptable for domestic use. Dissolved solids are mostly of the
calcium bicarbonate type and present in amounts less than 200mg/1. In
coastal areas, the quality decreases due primarily to high levels of mag-
nesium and sodium chloride.
Sediment loads tend to be low, primarily due to the lack of glaciers in
the area and the low annual runoff rates.
11.5.1.2 Ground Water
The ground water availability in the area is severely limited. Yields
from wells are usually less than 38 liters/minute (10 gpm), and are
generally located beneath the channels of larger streams and adjacent to
large lakes.
Springs are
the City of
year.
found in the area, including the
Nome which produces 374 to 1,136
Moonlight Springs used by
liters (100 to 300 gpm) all
c-66
—
LLw>.-=
1
C-67
0
Two major difficulties encountered with the developmer{t of ground water)
in the area are seasonal Iimita.tions and quality degradation. Numerous ‘
wells developed in the past have proven inadequate for year-round use,
as the wells have gone dry during the winter months. Improved siting
techniques and the use of galleries under stream channels may avoid this
problem.
Since most of the development in the region is near the coast, significant
problems with saline water intrusion into the wells has occurred. Though
the quality of water is expected to be higher away from the coast, avail-
able quantities may be decreased.
Inland, springs exist which have potential for providing year-round sup-
plies. Little information is available on these sources except for thosepresently in use and those located within the proposed Chukchi Imuruk
(Bering Land Bridge) National Reserve.
11.5.2 Water Use
11.5.2.1 Community Water Use
The population of the Norton Sound area is approximately 6,500, most of
which live in communities or villages along the coast. Water supplies
for community use include established treatment and distribution systems,
central watering points often with laundromats and showers, and organized
hauling and ice-cutting efforts. Table C-10 lists the communities, wateruse and supply facilities.
The communities shown in Table C-10 have populations ranging from a few
individual families to in excess of 2,500 people. Forty percent of the
communities have no system whatsoever. Another 30 percent have no dis-
tribution system, but merely communal facilities.
Many of the systems in use are functional only during the summer months
due to freezing, saltwater intrusion, or lack of supply during the win-
)
C-68
TABLE C-10
MATER SUPPL 1 ES IN NORTON SOUND COMMUNITIES
(-J
&lU3
●
Communities Present Pro jec ted /and Present Water Use’ Popul at ion’ Water Use*
Local ities Population* gal ./da.y) year 2000) gal ./day) Present Uater Source Present Water System P1 anned Improvements
Bluff 15’ 300 17 340 None None None
Bonanza i5’ 300 17 340 None None None
Boxer Bay 153 300 17 340 None None None
Brevig 194 6,790 2 2 0 7,700 Creek Storage: 300,000 gal. wood Minor maintenanceMission tank; PHS Central Facility
Cape Nome 15’ 300 17 340 None None None
Cape Prince 15’ 300 17 340 None None Noneof Males
Count i 1 35 1,225 40 1,400 Wel 1: 8-10 gpm winter 60’ VSW windmill; watering Minor maintenance3-5 gpm summer point
Oime Landing 15’ 300 17 340 None None None
Iliomede 125 4,375 141(Inalik)
4,935 Spring Storage: 120,000 gal. tank; Nonewatering point
Elim 288 “20,736 325 23,400 Spring; 80’ standby well Storage: 18:000 gal . wood Nonetank; distribution systemto al 1 homes
Gambel 1 447 15,645 505 17,675 Spring; (dries up in Storage: 100,000 gal. steel Identify new sourcewinter) tank; distribution system
to new homes
Golovin 118 4,130 133 4,655 Haul ice; rain water Storage: 300,000 gal. tank Locate new supplywel 1 (closed) watering point; PHS Central
Facility
Granite 15’ 300 17 340 Wel 1s; surface water Storage tank (winter NoneMountain source) for government
facilities
Haycock 15’ 300 17 340 None None None
King Island summer -- summer(Ukivok)
-- None None Noneonly only
Koyuk 160 5,600 180 6,300 90’ wel 1 (2 gpm) Storage: 2-800 gal. wood Distribution system to newtanks; watering point hones improve supply and
storage
Marys Igloo 15’ 300 17 340 None None None
Moses Point 15’ 300 17 340 16’ well (2 gpm) Serves FAA station None
● ●
f
● ●
—.—_ _Communl t les
andlocalities
Nome
NortheastCape
PortClarence
PiligrimSprings
St. Michael
Savoonga
Shaktool ik
Shelton
Snake River
Sol omon
Stebbins
Teller
Tin City
Jnalakleet
.Jngal ik
Present~iation
2,550
50’
15’
15’
283
409
163
15’
15’
15’
326
258
20summer
632
15’
—.—Present
Uater UseJl@@W)_
185,000
1,750
300
300
9,905
14,315
5,705
300
300
300
11,410
9,030
700summer
45,504
300
Populationyear 2000)
5,000
57
17
17
320
462
184
17
17
17
368
292
20summer
714
17
~roject edMater Usegal ./day)
360,000
1,995
340
340
11,200
16,170
13,248
340
340
340
12,880
21,024
700summer
51,408
340
TABLE C-10 (Cont. )
Present Hater Source
Moonlight spring (380 gpm)
Wel 1s
Shallow wells
None
Clear Lake
156’ well
Tagoonmenik Creek
None
None
None
Lake; well (school)
Coyote Creek
Wel 1
Powers Creek well
None
Present Water System
Stordge: 300,000 gal. con-crete tank; distributionsystem to half of homes
Formerly served militarysite; present use unknown
Storage for military site
None
Storage: 120,000 gal. tank;watering point
Storage: 103,000 gal. tank;watering point
Storage: 1,000,000 gal,tank; watering point; dis-tribution to new homes
None
None
None
Storage tank; wateringpoint; school has ReverseOZROS!: ?i-~;itinell~
Distribution to new homes;watering point
Storage tanks servesmilitary site
Storage: 1,000,000 gal.tank; distribution system
None
.
—— -—
Planned Improvements———
Nune
None
None
None
Moo new watering point
Expand distributionsystem
None
None
None
None
Full use of system whenpower supply reliabilityestablished
No~e
None
None—..
Communitiesand
Localities
Wales
WhiteMountain
TOTAL
PresentPopulation s
130
115
5,523
PresentHater Use’~al ./day)
4,550
4,025
345,290
147 5,145
13(I 4,550
9,490 569.,825
TABLE C-10 (Cont. )
Present Water Source
Spring (summer only)
Well (summer only)
Present Water System
Storage tank; wateringpoint (summer only)
Storage: two tankswatering point (summeronly)
‘ B a s e d o n r e g i o n a l p r o j e c t i o n s d e v e l o p e d b~ Univers i ty of Alaska, Inst i tute of Social a n d E c o n o m i c R e s e a r c h .‘ F igures accepted by the Alaska Department of Conxnunity and Regional Af fa i rs under the S t a t e ’ s M u n i c i p a l R e v e n u e S h a r i n g P r o g r a m .D E s t i m a t e d .* Estimated per capita use as f o l l o w s : (a) complete water system, 72 g/c/d; (b) watering point, 35 g/c/d; (c) no system, 20 g/c/d.
(3
● 9
Planned Improvements
Add 500,000 gal . storage
None
● * ● ●☛
☛
ter. Several of the systems collect water during the summer for storage
and use during the winter months.
As a consequence of the kinds of systems and the low populations, little
information is available on actual water use. The City of Nome reports
a per capita water consumption of 273 liters/day (72 ga~lons/day)* Other
data suggests that water use is significantly less in communities without
watering points and less still where no system exists. Water use estimates
of 132 liters/day (35 gallons/day) and 76 liters/day (20 gal~ons/day),
respectively, have been used for these situations.
11.5.2.2 Other Water Uses
In addition to the community water use,-water in the area is used for
mining operations, fish processing, and agriculture in the form of rein-
deer herds.
Mining operations in the area consist primarily of placer mines with a
few floating dredges in use. Though large amounts of water are used in
these operations, very little is consumed. Thus, the effects from these
operations are limited to some degradation of the water quality with
little effect on flows.
A plan to extract and concentrate fluorite, tungsten, and tin ores is
being implemented in Lost River. It is not known what water uses will
be required for this development.
Fish processing activities are located in Unalakleet, Moses Point/Elim,
Golovnin, Nome, Ungalik, and Shaktoolik. With the exception of the Nome
facilities, sea water is used for fish processing in all locations. At
Nome, a small amount of water may be taken from the city system, but this
is included in the community water use.
The only reported agricultural activity in the area which utilizes fresh
water is reindeer herding. Reindeer number about 17,000 in the area and
consume as estimated annual average of 126,514 liters/day (33,425 gallons/
c-72
day). In summer, water for the herds is available from ponds and streams
in the grazing area, and during the winter, the animals eat snow.
A pilot reindeer processing plant in Nome is used only sporadically, as
the bulk of the slaughtering takes place in the field, and little water
is used for this activity.
11.5.2.3 Restrictions on Water Use
Several other issues affect the use or development of water supplies,
including water rights, minimum flow requirements for fish, and land
designation. Winter construction activities have created problems in
the past by utilizing water from pools beneath frozen streams. These
pools often provide overwintering sites for various fish species and
the removal of this water seriously impacts fish populations. Conse-
quently, the Alaska Department of Fish i? Game strictly controls water
witttdrawals from these streams. Since this restriction coincides with
the low flow portion of the year, the availability of some sources for
year-round use may be limited.
●
●
Other fish and wildlife restrictions may apply to streams important to
anadromous fish, as shown in Table C-8. These Iirnjtations may affect
stream diversion, reservoir construction, and ether construction activities.
*
The ongoing process of division of lands between the state, the U.S.
Government, and native corporations presents some potentially restrictive
land and resource use constraints. Proposed land designations in the
Norton Sound ara include the Chukchi Imur~k National Reserve (Bering Land
6ridge), the Unalakleet River, the Koyuk River, and numerous MarineResources National Wildlife Refuges.
The proposed Chukchi Imuruk National Monument will occupy nearly three
million acres in the center of the Seward Peninsula. The implication of
this designation is that water resources within the monument or impzicting
this area are reserved for
undoubtedly complicate and
located within the area.
*
the purposes of the monument. This will
perhaps prevent the use of the water resources*
a
c-73 ‘
. . . . ..-. . . . . . . . . .
Two rivers in the Norton Sound area are proposed to be designated asI
“’Aild and Scenic”. This designation effectively prohibits the develop-
ment of these rivers. The Koyuk River from the mouth to where it enters the
Chukchi Imurak National Monument is one of these rivers. and the Unalakleet
River from twelve miles above the mouth to its source is the other
rivers are listed in Table C-8.
The sites proposed for designation as Marine Resources National Wi’
Refuges are all on offshore is”
little impact from these sites
supply development.
These
dl ife
ands or on the coastline. Consequently,
is expected on water resources on water
Following the resolution of the land withdrawal issues, the state is
expected to establish a State Recreation Area at Salmon Lake north of
Nome. This designation would complicate or prevent the development of
the lake or its tributary streams for water supplies.
Water rights in Alaska have traditionally been cont}$ol led by the StateI Department of Natural Resources. Recent land withdrawals associated
with the Alaska Native Claims Settlement Act have rtised the issue of
jurisdiction in the State’s allocation of water rights. At the present
time, one native corporation is suing the state, claiming aboriginal
title to the water rights within the corporation boundaries.
If this claim is upheld, it is probable that all existing water rights
within this village withdrawal areas would be voideq, and subsequent water
rights obtained through the native corporations. This could limit the
availability of water for development, depending upon the attitude of the
native corporation toward the development.
A similar situation exists with respect to former reservation areas,
as St. Lawrence Island and Elim. Though the state has been managing
such
waterrights in these areas, it is likely that, if contested, this jurisdiction
would be returned to the villages. This could also limit the water avail-
able for development.
)
c-74
III. Drilling Platforms
This section describes the various offshore drilling structures and ~ech-
niques that may be available to the oil industry in the Norton Basin OCS
lease sale area. These options are discussed in the context of the
dominant engineering constraints. It should be emphasized that many of
the technological options described herein are in the conceptual, design,
or prototype state of develo~ent, and thus, may require considerable
lead time before in~roduc~ion into an offshore petroleum development
program.
Particular reference is made to the Canadian experience in the southern
Beaufort Sea, arctic islands, and tlavis Strait/Labrador Sea, since they
are the only regions with significant offshore Arctic petroleum activity
to ~ate. This experience, discussed in Section I, includes:
● Exploratory drilling in the southern Beaufort Sea utilizing
soil islands, sunken barges, and ice-strengthened drillships.
o Orilling from reinforced ice platforms off the arctic islands.
e Exploratory drilling from dynamical ly-pmitioned semi-submersibles
and drillships in the iceberg-infested waters of the Davis Strait
and Labrador Sea.
* Advanced technological research in all phases of arctic offshore
petroleum-related activities.
In the Alaskan Beaufort Sea, as noted above, offshore exploration, activities
have been restricted to one ice island and three winter-constructed gravel
islands.
Review of the oceanographic conditions of
cates that modified Upper Cook Inlet type
Norton Sound (Section 11.1) indi-
platforms may be feasible in
Norton Sound since overall oceanographic conditions are not significantly
more adverse (also see discussion Section VII). A review of feasible explor- e
ation and development technologies for the OCS lease sale areas on the o
c-75 ●
current five year leasing schedule by Exxon (Offshore, April, 1979) indicated
that in Norton Sound exploration is seasonably feasible with mobile rigs and
development can probably be accomplished with gravel islands to 18 meters (60
feet) and “ice-resistant structures” to 61 meters (200 feet). Given these
considerations, this review of drilling platforms for exploration and/or
production focuses on artificial (gravel) islands, [jpper Cook Inlet type
platforms and monotone/ cone structures. Off-ice exploratory drilling
from reinforced ice platforms and ice islands is reviewed but is considered
to be of very limited, if any, application to Norton Sound given ice charact-
eristics and the other options available.
111.1 Artificial Islands
Artificial islands are generally constructed from locally mined soil (gravel,
sand, silt) with or without bonding or cementing agents and suitably pro-
tected to resist ice forces and wave and current erosion. An artificial
island may be designed as a temporary structure for an exploration well or as
a permanent production platform with long-term protection against ice and
waves. In the southern Canadian Beaufort Sea off the Mackenzie Delta,
artificial islands have been the favored technique for offshore exploration
drilling in shallow waters. A total of 17 have been constructed there to
date, mainly by Imperial Oil, Ltd.
The factors which favor this type of structure are (Riley, 1975):
Shallow water. The Imperial
about. the 20-meter (66-foot)
Oil, Ltd. lease acreage extends to
isobath.
Minimum sea ice movement. Most of Imperial’s acreage 1
in the landfast ice zone.
weather. Standby costs are very high for floating rigs
ies with-
during
the winter due to the short working season (2-1/2 to 3 months).
Ice forces. Islands were considered to be the safest means of
resisting ice forces.
c-76
cost* The initial capital investment for most other types of
structures was considered to be high compared with artificial
islands. This is especially important when the number of pro-
spective locations is small and very dependent on the ratio of
s~ccess.
Limited risk. Construction of artificial islands is a proven
technology utilizing standard construction equipment.
Governmental regulations. Environmental laws in Canada favor
this approach and do not require the removal of these islands
after their use for unsuccessful exploration drilling.
To date, artificial islands in the southern Canadian Beaufort Sea have
been built in water depths of up to 20 meters (66 feet) although such
structures may be feasible in water depths up to 30 meters (100 feet)
using caissons. Two islands were constructed in the summer of 1976, in-
cluding one in a water depth of about 12 meters (40 feet), and one in
the summer of 1977 in 15 meters of water (50 feet) of water (Croasdale,
1977). The most recent artificial island is “Issungnak” which is located
in 20 meters (65 feet) of water and took summer seasons (1978 and 1979) to
construct.
111.1.1 Design and Construction Techniques
Artificial islands are basically comprised of two parts: (a) a body of
the island which forms the base for drilling operations, with a minimum
surface radius of 50 meters (160 feet); and (b) side slopes designed to
protect the island from waves in summer and ice in winter (deJong, Stigter,
and Steyn, 1975; Ocean Industry, October, 1976). Croasdale (1977) reports
a typical island diameter of about 100 meters (330 feet) at the working
surface and 5 to 6 meters (17 to 20 feet) freeboard.
Island design is influenced by materials and techniques available for
construction as dictated by location and season. The surface area is
dictated by that required for drilling, and the freeboard by ice and wave
●
9
e
c-77
conditions. These factors will, therefore, determine island size and
fill requirements. Beach slopes, which also affect fill requirements,
are decided partly by construction techniques and foundation conditions
and partly by the requirement to protect the island ag~inst wave erosion.
Slope protection materials that are normally used, such as concrete blocks,
quarry stone, and bitumen mixtures, are very expensive in the Beaufort Sea
due to transportation distances. Short-term exploration islands, however,
can use such temporary
e Sand bags.
methods as:
@ Gabions (wire mesh enclosures) filled with sand bags.
Q Sand-filled plastic tubes, and filter cloth held down by wire
netting.
Typical island profiles are shown on Figure C-16; a sand bag retaining
wall was utilized for Netserk F-40, B-44, and Kugmal lit N-59, while a
sacrificial beach design was employed for Arnak L-3G, Kannerk G-4, and
Issungnak (Croasdale and Marcellus, 1977, MacLeod and Butler, 1979).
Three basic sand bag-retained island designs have been employed by
Imperial Oil to date (Riley, 1976; deJong, Steiger, and Steyn, 1975):
o Immerk type. Granular fill was hydraulically placed by suction
dredge, with a natural slope of 1:20. The Itnmerk B-43 island
was built during two summer construction seasons by pumping
sand and gravel from a submarine borrow site directly onto the
island site. The island was built to a height of 4.5 meters
(15 feet) above sea level in 3 meters (10 feet) of water.
o Netserk type. Mechanically-placed granular fill was dumpedinside and outside a retaining ring of sand bags; the side
slopes were 1:3. Netserk B-44 was built in 4.5 meters (15 feet)
of water with sand dredged from a borrow site 32 kilometers
(20 miles) from the island. A second island, Netserk NF-40,
was built in the same manner but in 7 meters (23 feet) of
water. fietserk was desinged for year-round drilling.
C-78
uSAND-BAG RETAINED DESIGN - PROFILE 1
+46 m =
SA
POLYFILTER SANOm,s. 1.
v
ND-BAG RETAINED DESIGN - PROFILE 2 R = 4 9 m+4.6m-
1.5 cu. m (2 yds ) SAND BAGS
POLYFI LT ER SANDm.s, 1.
-5.5 m+-
~\\Y /~A\\y/-/A \\w//h\\Yflf 4\\Y f
SACRIFICIAL . BEACH DEWC3N142- 206m~ Ilm 30m
98m ,\ 15m46m ~ ~
67-100 r,] 122-152m
N&al DESHORE PROTECYKiN
$ . 5
‘ “ ’ i 3 ’ ~ e -
CONSTRUCTION 40-45 DAYSFILL 1,2 million cu. m ( i.6million pu.yds.)
ANO MARCELLUS, 1977; CROASD~LE, 15177.SOURCE: CROASDALE
FIGURE C-”16 - T Y P I C A L I S L A N D P R O F I L E S
C-79 *
e Mgo type. Primarily silt was placed within a retaining wall
of sand bags by clamshell equipment. Adgo F-38 and P-25 were
constructed for winter season operations only and depended upon
freezing of silt to provide stable bases for equipment. Adgo
F-28 and P-25 were built with a limited freeboard to a mean sea
level (MSL) of +1 meter (+3 feet) in 2 meters (7 feet) of water.
Two islands, Adgo C-15 and Pullen E-17, were built during the winter
season by trucking sand and gravel over the ice from shore borrow sources
to the proposed island sites. Ice was cut and removed in blocks and the
excavation backfilled with sand and gravel. Slope protection was provided
by small sand bags. The islands were constructed to an elevation of MSL
+3 meters (+10 feet) so that they could be used during the summer. In
very shallow water in which barge-based equipment cannot operate, this
construction method has to be adopted. In the Alaskan Beaufort, all the
exploratory islands to date have been of the winter-constructed design
using onshore fill materials.
The sacrificial beach design protects the island through gradually
sloping (1:20 underwater slope) beaches which forc:e waves to break so
that their energy is dissipated before they reach the island. The beach
is thus sacrificed to protect the island. Since massive amounts of sand
are contained in the beaches, the island will remzin intact for several
storms* If necessary, the beach material can be replenished by additional
dredging.
In the summer of 1976, Imperial Oil constructed tyo sacrificial beach
islands, Anark L-30 and Kannerk G-42 (Engineering Journal, July/August,
1977) . The Anark Island, which is located in 8.5 meters (28 feet) of
water, was constructed of local sand borrow using a 32-inch stationary
cutter suction dredge. Sand was transferred to the island by floating
pipeline.
The Issungnak island currently holds the record for water depth and
fill requirements. It is located in 20 meters (65 feet) of water,
25 kilometers (15.5 miles) from shore. The island required 3.5 million
C-80
*
cubic meters (4.6 million cubic yards) of fill which was mainly obtained
hydropically from adjacent submarine borrow pits usinq the suction dredge
“Beaver Mackenzie”. During the 1978 construction season, 1.5 million
cubic meters of material were placed on the island by the suction dredge
which pumped fill at an average hourly rate of 1,136 cubic meters. Some
additional bor=row matwials were obtained from the Tuft Point site and
hauled in by dump scow. Two summer construction seasms were required to
complete the island.
ln 1975, Imperia? Oil’s construction spread in the’Beaufort Sea was com-
prised of (deJong, Stigter, and S~eyn, 1975):
24-inch cutter dredge
34-inch stationary suction dredge
five 1,520-cubic meter (2,000-cubic yard) battom dump barges
three 228-cubic meter (300-cubic yard) bottam dump barges
four 1,500-horsepower tugs
two 600-horsepower t~gs
one floating crane
four 5-cubic meter (6-cubic yard) clamshell cranes on spudded barges
one barge loading pontoon
The
are
The
has
floating pipelines
equipment requirements
shown in Table C-11.
111.1.2
design of
*
for a 20-island, 10-year exploration program
Construction Materials
artificial islands in the southern Canadian Beaufort Sea
beem determined in part by the availability and type of borrow
materials. Because the sea bed west of 134”W longitude consists pre-
dominately of silt, for which the consolidation process is slow, use
of local material is suited only to winter operations when the silt is
frozen. Consequently, except in a few cases where local sand was avail-
able, borrow material had to be hauled by barge for some distance for
island construction. In the construction of Netserk B-44, for example,
,.
*o
●C-81
TABLE C-n
ARTIFICIAL ISLAND CONSTRUCTION SPREAD
In order to construct and support a 20-island, 10-year program basedprimarily on caisson-retained islands, Imperial Oil, Ltd. suggest thefollowing (Canada Department of the Environment, 1977):
1977 Stationary suction dredgeCutter suction dredge4 - 1,500-hp tender tugs3 - 2,200-hp tugs4 - 4,000-hp dump barges4 - 7,000-yd dump barges3 flat barges2 floating campsSupport equipment
1978 Cutter suction dredge3 - 1,500-hp tender tugs4 - 2,200-hp tugs5 - 4,000-yd dump barges3 flat bargesFloating campCaissonBarge unloading dredge - c,~isson filledSupport equipment
1979 Add 1 - 2,200-hp tug4 - 4,000-yd dump bargas
1980 Add 1 - 2,200-hp tug1 caisson3 flat barges
Caisson filling equipment
1981-1986 Same as for 1980 I
C-82
*
fill had to be hauled 32 kilometers (20 miles). The enormous fill re-
quirements and economics of the sacrificial beach design require that
most borrow materials come from sources adjacent to the site.
Representative fill requirements for various types of gravel islands
are given in
111.1.3
The Canadian
landfast ice
Table C - 1 2 .
Ice Action on Islands
Beaufort Sea artificial islands have been located in the
zone, Landfast ice is relatively ;table, although move-
ments of several meters (feet) can occur. This amount of movement is
sufficient to impose significant loads on fixed structures. Ice action
on ice islands has been discussed in detail by Croasdale and Marcellus
(1977) and Croasdale (1977), and wil 1 be addressed only briefly here.
Islands in shallow, sheltered locations in the Canadian Beaufort (less
than 3 meters [10 feet] of water) are not subject to significant ice
action since the ice becomes stable soon after f’reeze-up; subsequent
movements are small and slow, with few observable cracks and ridges.
Ice movements are believed to be small enough and slow enough to allow
the ice to ‘flow’ or ‘creep’ around the island.
Ice around these islands during break-up generally melts in place. In
summer, the threat of encroachment from the poler pack ice is minimal
because the ice with jts ridges tends to ground in deep water.
In deeper water at exposed locations in the fall in the Canadian Beaufort,
ice takes longer to become truly landfast, and freeze-up is characterized
by large ice movements. This causes extensive ice rubble to form around
the islands, although the ice is too thin to ride up. When the ice
becomes landfast in November or December, ice movements are cyclical and
occur on the periphery of the ice rubble which has refrozen in place to
form a solid annulus around the island. Initially, the ice fails by
bending but as it becomes thicker it fails by crushing. At break-up the
ice rubble surrounding the island rapidly melts away, leaving the island
@
*o
C-83 ●
TARLE C-12
ARTIFICIAL ISLAND SPECIFICATIONS AND FILL REQUIREIW!TS
A. SP~C I FICATIONS Or SOW ~XPLORATION ISL4NOS CONSTRUCTED IN SOUTllCRN CANADIAN 13 fAUfORT 5EA ‘—.—— .——. -— —.—— .—. ——— ——-—— .—
T!~l~”d ~~~~~ Year
Adgo 1973
Immerk 1973
Net serk 1974
Netserk N 1975
Arnak 1976
Kannerk 1976[
X_E
Watermeters
21
3
4.6
7
8.5
8.5
5.2
13
*—-
7
10
15
23
28
28
17
43
Fillcu. met et-s
38,230
183,504
305,840
290,548
1,146,900
1,146,900
237,000
1,911,500
olume —
cu. yards
50,000
240,000
400,000
380,000
1,500,000
1,500,000
310,000
2,500,000
F r e e b o a r dmeters I f e e t
I1 I 3
4.6I
15
4.6 I 15
5.2 I 17
5.2 I 17I
4.6 15
4.6 15
I
iType I4
Sandbag RetainedI
Sacrificial Beach~
Sandbag Retained (
Sandbag Retained I
Sacrificial Beach ~
Sacrificial Beach I
Sandbag RetainedI
Sacrificial Beach i
‘a. COMPARISON OF F ILL REQUIREMENTS FOR OiFFERENT EXPLORATION ISLANO DESIGNS ‘ II I Retained Fill Island I Caisson Retained Island I
Mater Oeoth \ Sacrificial Beach Island (Sandbags) i 30 Ft. Set-Oown Depth Imeters I feet cu. meters Cu . yards cu. meters cu. yards cu. meters I yards
6 ~20 I CU150,000611,680 800,000 191,150 250,000 114,690
9 i 30 1,299,822 1,700,000 382,300 500,000 114,690 150,000 ‘
12 40 1,911,500 2,500,000 688,140 900,000 229,380 300,000
18 60 3,823,000 5,000,000 1,911,500 2,500,000 688,140 900,000
C o EST IMATEO REQUIREMENTS FOR PRODUCTION ISLANDS ‘
Water Depth Fill Volumemeters I feet Dimensions cu. meters C1l. yards
7.6 i 25 213 meters (700 feet ) diameter working surface, 665,202 870,0007.6 meters (25 feet) freeboard; 4:1 side slopes
15 50 213 meters ( 700 feet) diameter working surface, 1,376,280 1,800,0007.6 meters (25 feet) freeboard; 4:1 side slopes
Sources: ‘ deJong and Bruce, 1978a and b.‘ Oames & Moore estimates from various sources.
c-84
exposed to potential ice ride-up but such ride-up instead forms rubble on
island beach. Within the landfast ice zone, therefore, ice movement does
appear to be a significant problem. Research into the problem continues
since at exposed locations where polar pack ice may encroach, the poten-
tial exists for ice ride-up.
the
not
111.1.4 Cellular Sheet Pile Island and Caisson Retained Island
A cellular sheet pile island has been proposed as a feasible exploration
or production platform for arctic waters (Furssen, 1975). This concept
involves a “cells-in-a-cell” arrangement of sheet piling which is filled
with clean granular materials. To provide the requisite strength, the
fill is allowed to freeze back and, in the case of a permanent production
platform, is artificially refrigerated to maintain freezing. Thermopiles
could be utilized to accelerate freeze-up of the internal mass.
The minimum size of an exploration island is dictated primarily by the
minimum diameter acceptable to resist overturning, sliding, or internal
shear failureby ice loadings of up to 703,000 kilograms per square
meter (1,000 pounds per square inch); this diameter was determined to
be 60 meters (198 feet). In the case of a production island with only
the peripheral cells and annular space between the peripheral cells and
streamlined bulkhead containing frozen fill, a minimum of 150 meters
(495 feet) was calculated. In both the exploration and production
island designs, the interlocking cells would be 23 meters (76 feet)
in diameter. A freeboard of 8 meters (26 feet) is estimated to be
9
sufficient to resist overtopping by ice
For an exploration island, construction
days in one continuous operation. Fill
rafting.
would take 40 to
would be dredged
50 summer
and barged
in, and piling would be taken from onshore stockpiles. The construc-
tion spread would include a clamshell dredge, work barge, supply barge,
and camp for about 50 men. Construction of a production island would
take two seasons and would involve six crews with six driving templatesand cranes. As much work as possible would be done on the island from
completed cells.
●
C-=85
—
The advantages of a cellular sheet pile island include:1
o Reduction of fill requirements (over an artificial island).
● Strength against pack ice movement provided by cellular de-
sign and frozen fill.
@ Traditional construction techniques and readily available
components (piling, soil, ice).
Imperial Oil, Ltd. (Canada) has designed a caisson retained island for
exploratory drilling in the Beaufort Sea (deJong and Bruce, 1978a,
1978b) (Figure C-17). The caisson retained island consists of eight
trapezoidal ly-shaped caissons, 43 meters (142 feet) long, 12 meters
40 feet) high, and 13 meters (43 feet) wide at the base. The caisson
units are upheld together in a ring by two sets of stressing cables.
The design of this particular set of caissons is for 9 meters (30 feet)
of water with the caissons seated on the sea floor; in deeper water an
underwater berm would have to be constructed to an elevation of 9 meters
(30 feet) below sea level as a base for the caisson ring. The floating
caissons would be towed to the site in one of sever~l possible configu-
rations (single, back to back, rhombic or full octagonal), reassembled
to the octagonal configuration and ballasted on to the sea floor or
berm. Erosion protection material would be placed In the caisson ring
with a hydraulic dredge. The caisson ring is designed so that it can
be relocated each year. Disassembly would involve thawing of ice in
the ballast chambers, deballasting, removal of caisson connecting pins
when the caisson is afloat, and pulling of the two halves of the caisson
ring off the island, and transport for reassembly in rhombic configura-
tion. Representative fill requirements for the caisson retained island.are given in Table C-12, which demonstrates the significant reduction
in fill requirements for this design. The capital costs for the caissonunits (delivered) one estimated at $27 million (1978).
While the advantages of the caisson retained island for exploration are
re-use and significant fill reduction (over other gravel islands), the
c-86
0I
/’
t.
\
. .
,, . . .., .,.,! .,.., .
. . . .
.
I
r
.’#’
M
Ii:,..4. I1:
;. i
1
I,
\
●
#F-,.-,
/z\...
\
11;’/
iv
caisson retained island also has obvious merit for application as a
permanent production island with suitable modification for long term
protection from ice and waves.
Imperial Oil has proposed a 20-location, 10-year exploration program
mainly using caisson contained islands. These islands would be used
principally in water depths in excess of 8 meters (Z’6 feet) or where
there is a lack of suitable onsite fill to construct conventional
artificial soil islands.
111.1.5 Membrane Contained Island (Hydrostatically Supported
Sand Island)
A variant of the artificial island discussed above, which may have
arctic applications, is a prototype sand island field tested off the
south coast of England in 1976 (Ocean Industry, November, 1976; Dowse,
1979). The island, which could also be classified as a gravity structure,
consists of an impermeable rubber membrane filled with hydraulically
placed sand supporting a deck unit. The membrane and deck were fabricated
on land and towed to the site (at a 15-meter [50-foot] water depth) where
the fill was placed. Installation on site took less than 48 hours.
The design ofihe island is based upon the principle that at any depth
below the sea surface, the lateral pressure exerted by the sand is about
half that of the confining hydrostatic pressure. Thus, the sand behind
the membrane will always be stable, provided pore water pressure is
relieved; this is done by dewatering the sand through pumping during
placement of the fill and, when necessary, during operation by a permanent
pumping system. The dynamic response or energy absorption of the sand
island occurs through microstraining of the sand particles. This energy
absorption within the sand mass reduces the loading transmitted to the
structure foundation.
Unfortunately, the prototype, christened “Sandisle Anne”, was destroyed
during a storm in October 1976, which brought 10.6-meter (35-foot) waves
-- over 50 percent higher than the 6.4-meter (21-foot) waves predicted
c-88
. . . . . . .
(Ocean Industry, December 1976). No costs have been given for construc-
tion of this type of sand island.
Two other types of ice-resistant versions of this sand island have been
designed. One consists of two concentric retaining walls; the other an
outer wall sand structure surrounding a conventional gravity structure.
In both cases, the outer sand structure absorbs the shock while the inner
concrete or sand column supports the deck. The deck unit would be de-
signed to break ice. More recently, somewhat different designs have been
proposed for an arctic production drilling sandisle and arctic exploration
drilling sandisle (Dowse, 1979). The production sandisle, designed for
water depths up to 61 meters (200 feet) consists of a deck mounted on a
number of steel cylinders forming a peripheral ring (about 18 meters
~50 feet] high). Primary and secondary membrane bags would be attached
to the base of each cylinder. The construction sequence would involve:
(1) Tow in of the deck, with bags attached, on the site.
(2) Anchoring of the deck, inflating the bag with water and instal-
ling the drainage system.
(3) Installation of ~ gravel base layer in the bag, sand filling
and pumping.
(4) Completion of sa~d filling and installation of ground anchors.
As additional protection, a dredged sand berm could be placed around the
base of the structure. It is estimated that construction of a 16-ring
structure in 81 meters (200 feet) of water could be completed and drained
in two weeks. Development drilling would be conducted through the cen-
tral section of the island. Apart from the novel system of maintaining
structural integrity and resisting ice forces, and rapid construction
time, a major advantage of this structure is that it significantly reduces
fill requirements with its non-vertical walls.
●
9
●o●
C-89
111.2 Ballasted Barges
This technique employs a
then ballasted to sit on
barge floated to the well location where it is
the sea floor. A gabion/sand bag-contained
silt berm or sea ice thickening techniques are then used to provide
protection against waves and ice.
This ballasted barge technique was used successfully in construction of
the Pelly artificial island located in 2.3 meters (7-1/2 feet) of
off the Mackenzie Delta (Brown, 1976). The Pelly island locdtion
sisted of a drilling barge, base camp, dredge, and supply barges.
drilling rig was mounted on two rail barges, each 11 x 73 meters
water
con-
The
36 X
241 feet), tied together with a superstructure to make a slotted barge
27 x 73 x 4 meters (89 x 241 x 13-feet). The artificial island was
constructed with a gabion berm set on to the sea floor to form a rec-
tangle 155 x 164 meters (512 x 211 feet). The berm served as protection
against waves and as a retainer for silt fill which was placed around
the drilling barge.
The drilling barge system has the advantage of mobility (reuse) and
extension of the drilling season beyond that provided by an ice or siltisland. The Pelly island used conventional barges; their application
is dependent upon their size and draft. Modified conventional barges
are, therefore, restricted to a certain depth range
on the order of 1.5 to 5 meters ( 5 to 7 feet). To
shore in shallower water would require the dredging
which is probably
use them closer to
of a channel.
The ballasted barge technique could have greater application through
the development of a specially-designed drilling barge with a greater
depth range capability and possibly, protection against ice movement
that would obviate the need for a protective berm.
The ballasted barge concept also has possible application for produc-
tion facilities in conjunction with gravel or caisson-retained islands.
Modularized barge-mounted process units, fabricated in the lower 48,
would be towed to the site where they would be ballasted down or docked
in a basin located within a partially completed island. A berm or
caissons would then be placed around the barge mounted process units.
Such a concept is being considered by Beaufort Sea operators in Alaska
for production islands.
111.3 Reinforced Ice Platforms]
There are two types of reinforced ice platforms that have been produced
by thickening of the parent ice sheet through successive flooding of
its upper surface. In shallow water, successive flooding and freezing
of water on top of the parent ice sheet rapidly thickens and eventually
grounds the sea ice. Drilling can then be conducted from the thickened
and grounded ice sheet or artificial ice island. In deeper water, this
thickening technique has been used to gain the requisitebuoyancy to
support exploration drilling equipment.
111.3.1 Artificial Ice Island
The “ice island” concept involves the thickening of the parent ice
sheet to produce a grounded ice island (MacKay et al., 1975). Factors
limiting the usefulness of this concept include:
(1) Water depth.
(2) The rate of movement of the parent ice sheet.
(3) Rate of “artificial” ice growth.
(4) Ice strength properties of artificially grown ice.{5) Sea floor soil conditions.(6) Winter access only for construction.
(7) Maintenancee required by a quasi-permanent structure.
(1) Ice platforms and artificial ice islands are probably not feasible inNorton Sound due to large amount of ice movement in most cases, short winterseason (relative to the Beaufort Sea) and winter temperature limitations inthe amount of possible artificial ice formation. The discussion of arti-ficial ice islands and reinforced ice platforms is included here to provide *a comprehensive treatment of Arctic petroleum technology. ●
1 Advantages include minimum environmental impact, relatively low construction
cost in comparison to alternative structures, and no removal or minimal
restoration cost once the structure has completed its usefulness.
The key to the success of this concept is economical manufacture of high-
strength ice at a rapid rate. Since the number of ice-making days is limited
(40to 50 days) at 50 percent operating time during Janurary through May),
spraying or sprinkling of water has been suggested in order to increase
growth rates (Fitch and Jones, 1974). However, in most ice growth concepts,
the rate of ice growth appears to be inversely proportional to ice strength
in that more brine, which degrades strength, is included in rapid growth.
The most useful offshore areas for this concept appear to be in the landfast
ice zone in water depths shallower than approximately 10 meters (33 feet),
where sea floor soils are capable of developing adequate resistance to shear
forces. Use of an artificial ice island for exploration drilling appears to
have more advantages than disadvantages. This seems particularly true for/winter exploration inside the barrier islands. The cost of building, an ice
island (excluding development costs) has been estimated at less than $5
million (Fitch and Jones, 1974).
In the Alaskan Beaufort Sea, ice islands have been pioneered by Union
Oil Company of California, which constructed a prototype during the winter of
1975-76, and an operational island from which an exploration well was drilled
during the winter of 1976-77 (Dutweiler, 1977; Oil and Gas Journal, July 11,
1977) (Figure C-18). The operational island was located about 19 kilometers
(12 miles) north of Anachlik Island in Harrison Bay about 64 kilometers (40
miles) west of Prudhoe Bay. The island, which was located in 2 meters (8
feet) of water, consisted of an outer ice ring, 140 meters (462 feet) inside
radius, and an inner rectangular ’drill pad, 60 x 120 meters (198 x 396
feet). Surface flooding by gasoline-powered pumps in augered ice holes was
used to thicken the drill pad from the natural ice thickness of one meter tofour meters (3 to 13 feet), i.e. an addition of 3 meters (10 feet).
The outer ring was designed to protect the inner pad from ice movement and
act as an containment barrier in case of an accidental spill. The ring was
IN
111 1 ~ Drilling pad / J Ill
access
roddo 100 200 ft \/
‘---”” b’”o 6 0 m
SOURCE: OIL AND GAS JOURNAL, JULY II , 1977.
9
Figure C-=18 -= ICE ISLAND P L A N (UNION OIL)
●o●
c-93
constructed by placing snow berms on both sides of the ring rim and then
pumping water in the space to form ice. A 3.5-meter (12-foot) moat was cut
around 70 percent of the containment ring and kept ice-free for the duration
of drilling as further protection against ice movement.
The drilling rig equipment and supplies were brought to the site by Hercules
aircraft (total of 338 trips) which landed on a 2,000-meter (6,600-foot) ice
strip 0.6 kilometers (1 mile) from the ice island. The construction spread
for both islands was minimal relative to the normal equipment demands of a
land-based North Slope exploration well and included bulldozers, clamshell
crane, and pumps.
Construction of the ice island took from November 1 to January 15. The well
was spudded on February 17, drilling was completed on April 6 and rig down and
move-out accomplished by April 16. The island broke up in early July.
As a safety precaution, in the event of movement of the island, the well was
equipped with a release mechanism to permit rapid disconnect of the well. At
the edge of the ice ring, a second ice pad was constructed as a relief
drilling pad in the event a relief well had to be drilled to halt a blowout.
The disadvantage of an ice island is that the island only lasts for one
season and can only be used for one average depth well. In addition,
in the event of a late-season drilling problem such as blowout, there is
not the safety margin that a more permanent structure could provide.
111.3.2 Reinforced Floating Ice Platform
In the Canadian arctic islands, the Arctic Ocean is covered with ice 10 to 11
months of the year. About 12 wells in up to 305 meters (1,000 feet) of water
have been drilled off the ice from reinforced ice platforms by Panarctic
Oils, Ltd. since 1974. The Panarctic program was pioneered by the Helca N-52
well located off the Sabine Peninsula of Melville Island. It was drilled by
a conventional dryland Arctic rig with a subsea blowout preventer (BOP) stack
and riser (Baudais,
ally thickened from
water over a period
Watts, and Masterson, 1976). The ice sheet was artifici-
2 to 5 meters (7 to 17 feet) by free flooding with sea
of 42 days.
c-94
The single most important factor governing the feasibility of drilling
from an ice platform is horizontal ice movement. Consequently, such
platforms are restricted to areas of Iandfast ice where horizontal icemovement is not more than 5 percent of the depth of water over the design
life of the island. This can be explained by the fact that the three-
degree riser angle, which is the maximum that can usually be tolerated
in drilling operations, corresponds to a lateral motion in 200 meters
(660 feet) ‘of water of 10 meters (33 feet) (Croasdale, 1977). By con-
trast, in 20 meters (66 feet) of water, the permissible maximum lateral
ice motion would be only 1 meter (3 feet). Deep water, therefore,
mitigates the effects of any fast ice movement. Conversely, drilling
from a floating ice platform in shallow water, such as that which occurs
in the proposed State-Federal lease sale area of the Alaskan Beaufort and
inner Norton Sound, is generally not feasible.
The main disadvantage of the ice platform system in the Canadian Arctic
Ocean around Melville Island and adjacent islands is the time limitation
(and hence depth of we? 1 completion) imposed by the length of the season
of minimal ice movement (January to May). The [construction completion
date of the thickened ice platform is unlikely to be before the end of
December. Also, it should be noted that water c[epth must be great enough
that pack ice damage to
To produce the offshore
Island, a pilot project
was completed in 1978.
the BOP stack is not a problem. ●
gas reserves that have been
involving subsea completion
111.4 Ice-Strengthened Drillships
Dome Petroleum currently has three ice-strengthened
discovered at Melville
and a subsea pipeline,
e
drillships operating
in the Canadian Beaufort Sea (Jones, 1977) and a fourth was scheduled
to join the fleet in August, 1979 (Oilweek, Fekwuary 26, 1979). The
Canmar fleet will then consist of four drillships, seven ice breaker
supply boats, three ocean-going barges, a supply vessel, a new class 4
ice breaker (scheduled to join the fleet also in August, 1979), and a
leased ice breaker.
●c-95
The drill ships, which were moved into the Beaufort in the summer of
1976, have the capability of drilling up to 6,000 meters (19,800 feet) in
water depths between 30 and 300 meters (99 and 990 feet) (Brown, 1976).
They are 115 meters (380 feet) long and 21 meters (66 feet) wide, with a
light draft of 4 meters (13 feet) and a drilling draft of 7 meters (23
feet). Each have a dead weight of5,486 metric tons (5,400 long tons).
The drillships are anchored at the drill siteith a quick disconnect
mooring system which permits rapid release and reconnection of the
mooring lines in the event that a move off location is required due to
ice or other factors.
The Dome drillships are accomplished by seven ice-breaker supply ships
which have the capacity to break up to 1 meter (3 feet) of solid sea
ice. Each ship has the following specifications (Brown, 1976; Oilweek,
July 3, 1978):
Length - 63 meters (208 feet)
Midth - 14 meters (46 feet)
Draft -4.4 meters (14.5 feet)
Cargo capacity - 1,016 metric tons (1,000 tons)
Horsepower - 7,000 twin screw
Speed - 26 kph (14 knots)
Another proposed drlllship design is an ice breaking system using a
pneumatically-induced pitching system (PIPS) which allows drilling while
ice breaking (Ocean Industry, April, 1976; McClure and Michalopoulos,
1977) ● A detailed description of a Beaufort Sea ice breaking drillship,
including design and safety considerations and environmental parameters,
is provided by Jones and Schaff (1975)..
Ice-strengthened drillships could also be used in winter by maintaining
an ice-free “lake” in the landfast ice within which the ship could
operate. Methods proposed to maintain ice-free or thin-ice areas up to
300 meters (1,000 feet) in diameter include protective canopies, insu-
lating agents, hot water, air bubble generators, and the use of guardian
ice breakers (Jones, 1977).
C-96
111.4.1 Drillinq Program and Problems
A drilling season of about 112 days from July to October was planned for
the Dome ships in 1!276. However, in order to leave sufficient time to
drill a relief hole in case of an emergency, Catladian authorities limited
the drilling season by setting a mandatory comp”,etion date before the
projected end of the season (Jones, 1977). The 1977 drilling season was
longer since the ships wintered in the area at Perschel Island, and
drilling could commence immediately upon breakup without waiting for the
freeing of the Point Barrow entrance to the Bea~fort Sea. From 1976 to
the end of the 1978 season, Dome had only been ~ble to drill a total of
135 days (Oilweek, February 26, 1979).
By the end of the 1977 drilling season, Dome’s c~rillships had drilled
(completed or partially completed) six exploratory
Beaufort Sea. In 1977, three wells were spudded:
Tingmiark K-91, and Nektorolik K-59. The original
work barge to install a 6~meter (20-foot) diameter
wells in the Canadian
Kopanoar D-14,
plans required a
caisson (for BOP
protection) before the dril?ships arrived on location. However, due toproblems experienced duripg preliminary work in 1975, Dome used the
simpler technique of placing well heads and BOP stacks in scooped-out
depressions in the sea floor out of reach of scouring ice [Jones, 1977).
The Hunt Dome Kopanoar D-14 well was drilled to a depth of 1,150 meters
(3,795 feet) but was abandoned aftera high-pres.sure water flow was
encountered which rose to the sea floor outside the casing (OCS Environ-
mental Assessment Program, 1977a). A well was @il,led alongside theabandoned casing to the water-producing formation at 558 meters (1,840
feet); by the time the relief well had been drilled, the water flow had
ceased of its own accord. Dome was required to reinspect the well, wherea smal? water flow had started again, in the summer of 1977 prior todrilling at the new Kopanoar location (OCS Environmental Assessment
Program, 1977b). A replacement well, Kopanoar M-13, was spudded 200
meters (660 feet) away and casing was set at 380 meters (1,254 feet)
prior to suspension at the end of the 1976 drilling season (Oil and Gas
Journal, June 13, 1977).
*
9e●
c-97
t The Tingmiark K-91 well was suspended and shut in after a high-pressure
natural gas zone was encountered. Subsequently, a leak of salt water was
discovered issuing from a fissure in the sea floor 6 meters (20 feet)
from the well head.
In 1977, drilling started again at the Kopanoar M-13 and Nektoralik KY59
wells, and a new well, Ukalerk C-50, was spudded. Gas was discovered
at all three 1977 wells, and oil was discovered at a depth of about 2,590
meters (8,547 feet) at Nektoralik K-59 (Oil and Gas Journal, September 26
and October 10, 1977). A drilling extension beyond a September deadline
for the Nektoralik well was granted priorto the oil discovery by the
Canadian government in order to permit Dome to complete drilling through
the gas zone and set casing. After operations for the 1977 season were
suspended at the Kopanoar M-13 and Ukalerk C-50 gas discovery wells,
the drillships were released to set surface casing at’the Natsek E-56
and Nerlerk M-98 well locations which had received preparatory work
earlier in 1977 prior to the termination of the shallow drilling season
at the end of October; (Oil and Gas Journal, October 10, 1977). The
1977 discovery wells were scheduled to be tested in 1978. The water
depths at the three 1977 wells range from 27 meters (89 feet) at Ukalerk,
56 meters (185 feet) at Kopanoar, and 63 meters (208 feet) at Nektoralik.
The 1978 season, which ended October 5 as mandated by the Canadian
government, involved re-entry of three of the earlier wells and spudding
of four new wells. In 1979, re-entry of four of the earlier wells,
including the major discovery Kopanoar M-13 (originally spudded in the
first season -- 1976), and spudding of four new wells was planned. The
Kopanoar M-13 well was completed to a depth of4,485 meters (14,714.feet)
and tested at 6,000 b/d of oil from a 61 meter (200 feet) pay zone at
3,505 meters (11,500 feet). To date four oil and gas and condensate
discoveries had been made by Dome.
Dome believes that it is technically feasible to drill narly year-round
Iwith ice breaker support.
C-98
111.4.2 Application to Norton Sound
The use of ice-strengthened drillships permits exploration drilling in
deeper water than do artificial islands. However, there is a minimum
water depth (about 20 meters [66 feetl) in which drillships can operate
due to limitations on lateral motion of the vessel that are dictated by
the riser- angle.
Ice-strengthened drillships and conventional drillships will both have
application in the Norton Basin lease sale. While water depths in the
inner and central sound are generally too shallow for drillships (18
meters [60 feet] or less), water depths in the outer sound -- northern
Bering Sea area are within the operational capabilities of drillships.
Although the open water season is longer than that in the southern
Canadian Beaufort Sea, the length of the season will still restrict
the number of wells that can be drilled (see discussion below). To
accelerate the exploration program and field delineation, the use of
ice-reinforced drillships with ice breaker support may be economically
justified in the northern Bering Sea.
As the Canadian program has demonstrated, it can take up to three seasons
to drill and test (in the event
111.5 Ice-Resistant Structures
111.5.1 Monopod
of a discovery) an exploration well.
●
The monopod platform is one configuration of a variety of gravity
structures that are grounded on the sea floor after being floated to the
site. The base of the platform may be attached to the sea floor by
piles. The monopod design was employed successfully by Union Oil for a
production platform in Cook Inlet in”1966 where seasonal ice moved by
strong currents can be encountered from November to May (Oil and Gas
Journal, March 2, 1970). The platform was designed for 20 meters (66
feet) of water, a 9-meter (30-foot) tidal range,. a design wave of 8.5
c-99
meters (28 feet) with a period of 8.5 seconds, steady force loads of
21,090 kilograms per square meter (43,200 pounds per square foot), and a
bearing area based on a 2-meter (7-foot) ice thickness. The monopod
consisted of a single column (in which the wells were located) resting on
twin pontoons. The pontoons were connected by horizontal bracing members
through which pilings were driven. The drilling deck and production
deck, total ling 1,114 square meters (12,254 square feet), were located 33
meters (109 feet) above the pontoons.
The advantages of the monopod are (Croasdale, 1977):
(1) The amount of
minimized and
(2) Ice action on
frontal area that is exposed to moving ice is
does not vary with water depth.
the structure involves crushing failure, for
which structures in sub-arctic regions such as Cook Inlet havebeen designed.
(3) An increase in ice forces due to ice freezing to the structure
will not be as great as that which might be expected with
adfreeze on a sloping surface.
(4) There is no chance of ice-ride onto the p?atform+s working
surface.
Recent research on ice loading in the Beaufort Sea, which indicates that
in water depths greater than 10 meters (33 feet) thick multi-year ridges
might impose loads as much as 300 MN (67 x 106 lbf), coupled with research
that indicates conical structures could resist such ice features better
th’an cylindrical structures, would suggest that mortopod structures may be
of limited use in” the Beaufort Sea but feasible in Norton Sound where ice
forces are less. Canadian research emphasis has, therefore, been On conical
structures.
Imperial Oil of Canada has designed”a monopod
exploration drilling in the southern Beaufort
c- 100
platform for year-round
Sea (Brown, 1976). This
monopod is a one-legged platform supported by a broad submersible base
and is designed for the. environmental and soil conditions existing out to
12-meter (40-foot) water depths. The monopod structure consists of three
main components: the hull, shaft, and superstructure. On location, only
the shaft is exposed to ice loading since the hull is totally concealed
in a previously prepared excavation on the sea floor. The monopod is set
down on the sea floor or floated by ballasting or deballasting tanks
contained in the hull. Beyond 12-meter {40-foot} water depths, it is
postulated that concealment of the hull and pressure-ridge keels is
remet e. A similar design described by Jazrawi and Davis (1975) is
presented in Figure C-19.
A mobile gravity structure such as the monopod provides operating flexi-
bility for exploration and could probably operate in greater water depths
than can he served by gravel islands. All of the well casings must be
placed in the single shaft.
111.5.2 Cone
An alternative configuration to the monopod is a none which causes a
moving ice sheet to ride up and fail in tension with both radial and
circumferential cracks (Gerwick, 1971). The coni:al shape reduces the
ice force on the structure by causing the ice to fail by bending rather
than crushing. ‘T’his is particularly important in areas affected by
multi-year ice ridges. In order to prevent excessive ice ride-up, the
cone would recurve at the top beneath the superstructure. A cone struc-
ture could be of concrete construction designed to be ballasted on the
sea floor.
Considerable research on the cone structure, including model testing
with ice, has been conducted by Imperial Oil, Ltd. under a coordinatedprogram of Arctic research sponsored by the Arctic Petroleum Operators
Association (APOA). The reader is directed to papers by Croasdale
(1975; 1977) , Croasciale and Marcellus (1977), Ralstan (1977), and
Pearce and Strickland (1979) for discussions on ice forces and ice
interaction with offshore structures such as the cone.
*
●
●e9
C-lol
70 m
(
I 10lm -i
SOURCE: CROASDALE, 1977; JAZRAW! ANO DAVIS , 1975.
Figure C-19
CONCRETE MONOPOD
C-102
A variant of the cone design is an “ice island” (not to be confused with
a thickened ice sheet), which consists of a 76-meter (250-foot) tall
hour-glass-shaped steel-plated platform capable of operating in waters up
to 20 meters (66 feet) deep (Oil and Gas Journal, September 14, 1970).The steel plate shell is supported by ice-filled tubes in compartments.
The structure is floated to location during the open water season and
ballasted to the bottom with seawater, which is then refrigerated to
provide the strength for additional resistance to ice forces. Refrigera-
tion requirements have been calculated for initial freezing and for
maintenance of the ice through the winter and following summer seasons.
To move off location to another drilling site, the frozen fill is thawed,
and the internal compartments emptied. The cost of this structure was
estimated at $40 million in 1970.
The cone design, unlike many of the options described in this chapter,
is one that is being considered for operations outside the Iandfast ice
zone, in areas subject to ice ridge movement (i.e. ground ridge zone and
seasonal pack ice zone).
111.5.3 Monotone
A hybrid design of the monopod and cone is the monotone which consists of
a monopod within a conical collar attached at the ice line. The monotone
configuration is expected to be less expensive in deeper water than a cone
and also has a smaller diameter at the water line to keep ice friction and
adhesion low.
At the 1979 Offshore Technology Conference specifications on an arctic
production monotone were presented (Stenning and Schumann, 1979). This
platform has been designed for year-round operation in the Beaufort Sea
in medium water depths of up to 76 meters (250 feet) (in the shear ice
zone). The structure comprises three basic components: (1) a doughnut-
shaped base which can either be a gravity base or piled unit depending
on soil conditions, (2) a bottle-shaped superstructure that can be dis-
connected from the base to avoid ice-island collision, and (3) a removable
jack-up deck. The structure pierces the surface with avertical shaft
rather than a sloped cone.
o9
*
●o
C-103
The structure, minus the deck, would be towed to the site vertically (three
9,000 horsepower tugs would be required to tow the monotone at a speed of 3
knots) and ballasted down to the sea floor in several submergence stages.
The deck consists of two Integrated barge units which are towed to the site
and attached to the shaft and jacked into position. The deck is a four-
story, fully integrated unit with an overall dimension of 75 x 58 x 18 meters
(150 x 190 x 60 feet) sized for the assumed 120,000 bpd production.
Construction scheduling would involve towing the structure around Point
Barrow in the early summer (with ice breaker support) and installation on
site, deck installation the same summer and commissioning in winter. This
schedule would be somewhat shorter than the offshore construction time for a
large North Sea platform. The integrated barge deck combined with the unique
jacking system for deck installation minimizes offshore construction time.
Specifications and design parameters on the Arctic production monotone are
given in Table C-13.
An alternate design involves three slim conical legs supporting the deck.
The arctic production monotone could have application in Norton Sound if
ice forces were found to exceed the design capabilities of the monopod and
other Cook Inlet-type platforms.
In the Beaufort Sea, the economic cut-off for utilization of a caisson-
retained island vs. gravity structure such as the monotone is uncertain.
Caisson-retained islands are technically and economically feasible to
a maximum depth of about 46 meters (150 feet) assuming adjacent borrow
materials. Beyond this depth, gravity structures are the principal eco-
nomic and technical option. In intermediate water depths (18 to 46 meters
[60to 150 feet], selection of the prefered system would depend upon gravel
availability and technical design considerations such as ice movement, sea
bottom soils, reservoir characteristics and transportation strategies.
C-104
TABLE C-13
SPECIFICATIONS AND DESIGN CRITERIA - ARCTIC PRODUCTION MONOCONE
IM!Q TABLE 2
WGNM4T SUMMARY GENER,,L DESIGN CRITERIA
sucwfwuctwe: Wrqh; m Kim 1 . kign Water Oapth: 200 feel r. Sail Condition
stool 37.3M 2. Swvica Life 25 vtar$ Grawtv he Piled BaseCaufa* ~ 3. Oee19n Tonmwaturn Anoverconsohdmd 0’
62,103 :Pi144 8*” (*,eludmQ #,1”1 ! Minimum Air Tempwat.ra .S&F cky soil wtth an un. 3
S:* 26.400 Maximum Air Tmn@eraNm +80”F g 100dramcdshear $trength ~0,603
b
weak clav sod
vm Minimum Watw Tem@rature 27’F of 2503 PSF. ~
Pilel (rJlt Clef Iodl:5
4 . Oceen Cwramsc 20!Y2
stool 70,m Maximum Surface Curr@nt 3knotsGl@WtV 8- IwI!I!ou4 bdnll Mwumum Bottom Currmt 1,5 knots 1000 2000 30W
Swcl 32x(3 NOM: OWratiMWr?ants Me taken coheswes hcarwrength (PWCerlcrwt 14,JW
4G as 213 of Maximum. %.. tce COndttiOfm
Oek Imt,ndud,m mu$o. wewlt:5 . Saismic CcNtditiens: Maximum. A l~~!h,ck mult,.year ridge comb,ndy,ll)a
Maximum Firm Ground Accelarmiom$tWCtW*lW091Not O<ck 1 S,020
10 [hick multi.vew Ice sheet
J=kq Svnmm 5U0 a a percmmgc of prwity 8.8% Operating. A SO’ thick muki.vear ri~ combined w,lh az Note: Thhcormrmnds lb NBC 10’ Ihack mult#.vew@3hcet. ..*
TOTAL STRUCTURE WflltM4T (no muionwntl: zone 3 Q OOwating COnditiOnn
G?wwslmewo 1?4<200 6 . bstaw: Producwn Rata: f20.00080Pomea sMulXum 183.000 Maximum Wave Heqht 35 feet Rerwwed No, of Wetls 40
Predominant Wew Period 10 seconds No, of Wells Or!lld Per Re$uoulv: 2
Source: Stenning and Schumann, 1979.
C - 1 0 5
111.5.4 Upper Cook Inlet Type Platforms
Fourteen platforms have been installed in Upper Cook Inlet. of these,
most were four-legged structures, two had three legs, and Union instal”
a single-legged monopod platform (Visser, 1969). The environmental
forces for which these platforms have been designed include: a latera”
load of 10,000 kips and vertical load of 10,500 kips. In the final
design, wind, wave, and earthquake forces were neglected because they
d
were found to be small compared to ice forces. Tidal variations in Upper
Cook Inlet are in excess of 9 meters (30 feet).
To accommodate these environmental forces, Cook Inlet platforms incorporatethese design principals:
o Columnar legs without cross bracing and tidal zone, reinforced
with concrete inside.
s Risers located within the legs.
o Special “pulltubes” installed within the structural members to
reduce dependence on diver assistance in pipeline hook-ups and
the amount of underwate welding, and protect pipelines from
possible ice damage.
If forces are not significantly greater in Norton Sound, then Cook Inlet
type platforms may be the favored platform option. Given the Cook Inlet
experience, such platforms can be submerged, piled down, and have deck
and modules installed within a four month open water season. Development
drilling could commence
111.6 Other Platforms
in the following fall or winter.
There are several offshore drilling systems proposed for ice-infested
areas that are in the conceptual or design stages.
One such system is a semi-submersible drilling rig design studied by
APOA . The design consists of a lower hull located well below the water
C-106
surface, a monopod column supporting an ice-cutting cylinder, and a
superstructure containing the drill rig, crew quarters, etc. The semi-
submersible is evisioned to be a self-propelled and dynamically positioned
drilling system. In sha?low water areas, the
could be employed as a gravity structure rest”
ballasting.
Another system is the dynamically positioned 1
platform, “Rock Oil”, designed by a Norwegian
seri-submersible system
ng on the sea floor by
loating arctic drilling
engineer (Ocean Industry,
March, 1976). The platform is a partially submerged steel tank in the
form of a 32-side rhomb, 11.3 meters (373 feet) in diameter, and with a
total height of 120 meters (396 feet) from the bottom of the tank to
the top of the drilling derrick, which supports a deck and steel tower.
A propulsion system with driving propellers set at the base of the tank
45 meters (149 feet) below water level, coupled with ballasting/debal-
lasting capabilities, would provide the structure with ice breaking
capability.
●
For operation in landfast ice areas, an air cushion drill barge (ACDB)
has been proposed (Jones, 1977). The ACOB is a d~ill rig mounted on
an amphibious air cushion platform which can be used on ice or in alake previouslyprepared in the ice sheet by removal of ice blocks.
Iv. Pipelines
Offshore pipelines in Norton Sound will be laid by conventional lay barge
or reel barge equipment in the summer open water season. For the repre- ●sentative distances to shore from hypothetical Norton Sound discovery
sites, most trunk lines could be laid in one summer season given an average
laying rate of about 1.6 kilometers (1 mile) per day for large diameter
lines and up to 3.2 kilometers (2 miles) per day for small diameter ●lines. If extensive burial was required for the longer lines, i.e. on
the order of 128 kilometers [80 milesj, however, a project may take more
than one season to complete. The maximum offshore pipeline distance that
can reasonably be anticipated in Norton Sound is about 128 kilometers
(80 miles).●o
●C-107
Offshore pipeline design in Norton Sound would have to take into consid-
eration the geologic hazards described in Section 11.2 such as unstable(liquefiable) soils and sand wave zones and ice gouges in shaliow water
dress dnd at shore approaches. Special insulation woljld probably be
required for pipelines in these frigid waters.
A particular problem for pipelaying activities, as with other offshore
construction, in Norton Sound will be the logistics of resupply and the
provision of pipe storage and pipecoating facilities. While the Aleutian
Islands provide several potential sites for such support bases, supply
lines are long and re-supply turnaround correspondingly protracted. Such
delay may be preferable, however, to the significant investment costs for
a Norton Sound facility with generally unfavorable conditions for port
siting. Alternatively, floating support bases, barges, or freighters
could be adopted.
v. Offshore Loading
To develop potential Beaufort Sea reserves, Dome Petroleum has proposed
a marine delivery system that involves offshore processing and loading
of crude or LNG from an artificial island to ice breaking oil or LNG
tankers support by an arctic class 10 ice breaker called the “Arctic
Marine Locomotive” or AML (Dome Petroleum, 1977, 1978). Dome believes
that such a system is economically and technicall~y feasible and pre-
ferable to pipelining production to a shore terminal or MackenzieValley oil pipeline.
Dome has designed and costed a steel wall earth-filled caisson production/
storage/loading island for 21 meters (70 feet) water depth. The structure
consists. of an outer ring well wall and inner ring wall with the inter-
annu”
down
ring
ar space filled with sand. The caisson modules would be ballasted
on a submerged fill berm about 6 meters (20 feet) high, the outer
caisson, consisting of 12 modules, would be about 27 meters (90 feet)
high, allowing for a 12 meter (40 feet) freeboard, and 55 meters (181
feet) wide, and have a diameter of 244 meters (800 feet). The inner ring
consists of a central storage tank with a 3 million barrel capacity, made
from 2 to 4 curved modules, and has a diameter of 131 meters (700 feet).
C-108
With three million barrels of crude storage and an assumed peak production
of 100,000 b/d, the field would be served by two-200,000 DWT ice breaking
tankers built to arctic class 7 standards. The ships would operate
year-round between the Beaufort field and the U.S. east coast -- 8,385
kilometers (7,525 nautical miles). Each ship would average
per year carrying 1.5 million barrels with an effective del
50,000 b/d. An arctic class 10 ice breaker, the AM1., would
tanker operations to assure year-round transportation capab
12.6 trips
very rate of
support the
lity. The
100,000 b/d system would cost about $425 million (1978) including $91
million for the caisson island with processing and docking facilities,
$38 million for the crude oil storage tank, and $296 million for two icebreaking tankers.
Dome has also proposed a similar offshore LNG system consisting of a
caisson-retained island with modularized liquefaction plant (one BCF
capacity in four trains) and three 80,000 cubic meter cryogenic storage
tanks. A fleet of eight 125,000 cubic meter ice-strengthened LNG carriers
would be required to transport the LNG to a U.S. east coast destination.
Total system cost is estimated at $2,290 mil lion (1978).
Dome believes that such systems are technically and pconornically feasible
for the Alaskan OCS areas with significant sea ice.
VI. Application of Offshore Loading in Norton Sound
Most potential discovery locations in Norton Sound are probably within
economic pipeline distance to shore (Table 3-2). Generally when discov-
eries are made close to shore and in the vicinity of other fields,
pipelining to a shore terminal is the favored development strategy due to
the technical constraints of offshore processing and loading. Furthermore,
sea ice would present special engineering design problems to offshore
loading hardware over and above those experienced in
such as the North Sea.
However, in some adverse discovery locations where a
from a suitable shore terminal and remote from other
open-water areas
field is distant
discoveries (with
●
●
●
C-109
which it could share
opt ion. Two areas of
distant from suitable
northern Bering Sea m
Peninsula.
nfrastructure) offshore loading may be a limited
the potential Norton Basin lease sale area are
shore terminal sites: the Yukon Delta and the
d-way between St. Lawrence Island and the Seward
VII. Production System Selection for Economic Analysis
In an oceanographic comparison with Upper Cook Inlet, on the one hand,
and the Beaufort Sea on the other, Norton Sound and adjacent areas of
the Sering Sea have certain attributes and problems of both and yet are
unique in other aspects. Table C-14 compares the design-related oceano-
graphic conditions of Norton Sound and Upper Cook Inlet. Norton Sound is
shallower than Upper Cook Inlet, deeper in general than the Beaufort Sea
lease sale area, and has ice conditions in terms of duration intermediate to
both. Water depths range from 7.5 meters (25 feet) off the Yukon Delta (i.e.
at the three-mile limit) to over 46 meters (150 feet) in the outer sound
between St. Lawrence Island and the Seward Peninsula. Pack ice up to 12
meters (40 feet) thick has been reported in the Bering Sea although floe ice
within Norton Sound is generally up to 2 meters (6.5 feet) thick. Shorefast
ice extends shoreward of the 10-meter (33-foot) isobath. A maximum wave of
about 4.3 meters (14 feet) can be anticipated in Norton Sound. These
preliminary oceanographic findings, in conjunction with design criteria
for Upper Cook Inlet steel platforms, indicate that modified Upper Cook
Inlet type-platforms may be feasible for operation in Norton Sound. This
conclusion is tentative since sufficient oceanographic data to adequately
assess platform design requirements does not yet exist. However, such
platforms, as opposed to the monotone proposed for Beaufort Sea operations,
may be the more likely development strategy.
Integrated barged-in deck units may be utilized to reduce offshore con-
struction time due to the short summer weather window.
In the shallower waters of the Norton Sound (23 meters [75 feet]), depending
)upon gravel availability and environmental sensitivity, gravel islands and
caisson-retained gravel islands may be technically feasible. Modularized
barge-mounted process units, ballasted down and surrounded by gravel berms
C-no
TABLE C-14
Oceanographic
Condition
COMPARISON OF DESIGN RELATED OCEANOGRAPHIC
CONDITIONS IN NORTON SOUND & UPPER COOK INLET
Water Depths
Tidal Currents
Tidal Ranges
Ice Coverage
Ice Thickness
Max. Ice Forces
Max. Sign. Design
Wave
Norton Sound
15-49m (50-160 ft.)
36 cm/S~C (0.7 Kts)
0.5-l.3m (1.5-4.2 ft. )
100% - complete
2m (6.5 ft.)
Unknown
6.lm (20 ft. )
Upper Cook Inlet
9-137m (30-450 ft. ) ‘1)
420. cm/sec (8 Kts)
4.9-9.Om (13.8 -29.5 ft. )
50-70% - broken
1.5m (5ft.)
21 ‘g/cm2 (300 psi)
8.5m (28ft.)
(1) Extreme depth near West Forelancf; most of Upper Cook Inlet has waterdepths less than 76 meters (250 feet).
*
●
●
Sources: See references cited in text
I or caissons may be the favored engineering strategy for gravel or caisson-
retained production islands.
In summary, the following platform types and representative water depths
were selected for economic eva”
platform Type
Ice reinforced steel plat
uation: (1)
o rm(modified Upper Cook Inlet Design)
Water Depthmeters feet
15 5030 10046 150
Gravel Island 7.6 2515 50
Pipeline distances representative of potential discovery situations (in
the context of geography) were identified for eocnomic screening as
shown in Table 3-2. In addition to development cases assuming pipelines
to an onshore crude oil terminal for LNG plant, offshore loading from a
production/storage/loading island was selected for consideration of the
economic analysis for comparative purposes although the costs of such a
system are especially speculative.
(1) Subsea completions were not evaluated in the economic analysis dueto the great uncertainty of costs for equipment to operate in such a harshenvironment. That is not to say subsea completions would not have a rolein Norton Sound petroleum development. Subsea completions can be used (1)in conjunction with fixed platforms to drain isolated portions of a fieldthat cannot justify installation of a fixed platform, (2) in conjunctionwith floating platforms (e.g. North Sea Arq.yll field --we evaluated suchsystems in our Gulf of Alaska reports), or-~3) as an integral part ofplete subsea production system. Year round maintenance and ice scourshallow water areas are two ofin the selection and design of
the problems that would have to be conssuch subsea systems in Norton Sound.
om-ndered
C-112
Given the estimated oil and gas resources of the Norton Basin, all the
development options considered in the analysis assumed tankering of crude
or LNG to lower 48 markets.
As discussed in Appendix B, construction schedules and manpower estimates
developed in this study assumed extensive modularization and integration
of onshore and offshore facilities to minimize local construction and speed
construction schedules because of the short summer weather window of four
to six months.
Exploration and production platform options and their application are sum-
marized in Table C-15.
C-113
●
●
TARLE C-15
SUMNAR’f OF EXPLORAT I OH ANO PRODUCTION PLATFORM OPTIONS
EXPLORATION
Jack-up rig
Semi-submersible
Gravel island
Gravel island-summer
Caisson retained
Monotone
Orillship
Ice-resistant drillship
PRODUCTION
Gravel island
Caisson retained island
Monotone
Cook Inlet type
Watermeters
3+
46+
0-4.5
3-18
9-18
7.6
21+
21+
3-18
9-46
46+
6+
?th’feet
10+
150+
o-15
10-60
30-60
25-150+
i’@-
70+
10-60
30-150
150+
20+
Application ot Norton Sound Area/Comments
Summer only
Summer only, water generally too shallow
Little of lease sale area in these water de~ths
Use restricted by gravel availability andenvironmental problems
Use restricted by gr~vel availability andenvironmental problems
Possible, could extend drilling season (onlydesign stage)
Summer only
in
Yes, could extend drilling season with ice breakersupport; most of central and inner Norton Soundtoo shallow for use of drill ships
Use depends on gravel availabmental acceptability
Use depends on gravel availabmental acceptability
ity and environ-
ity and environ-
Use depends on ice forces; caisson islands, andother structures may be more economic
Use depends on ice forces
‘ Range of water depths specified reflects technical and probable economic feasibility.
Source: Dames & Moore compilation from various sources (see text).
C-114
.
APPENDIX D
●a
—. . . .— —
APPENDIX D “
PETROLEUM FACI-LITIES SITING
I. Introduction
In Norton Sound most, if not al?, the crude will be exported to the
lower 48 states. Some oil may be destined for refining in Alaska
(e.g. Upper Cook Inlet) but that will also be shipped by tanker dueto lack of onshore transportation facilities. Onshore pipeline terminals
will serve, therefore, as transshipment facilities. Depending on the
type of crude produced, the terminal will complete stabilization of the
crude, recover liquid petroleum gas (LPG), treat tanker ballast, provide
storage for about ten days production, and have loading jetties for crude
and LPG tankers. The cost of the terminal will be borne by the offshore
field(s) it serves. Given the U.S.G.S. resource estimates, it is unlikely
that a pipeline would be constructed across western Alaska to the Fairbanks
area to take Norton Sound crude to the trans-Alaska pipeline (assuming
that the trans-Alaska pipeline had surplus capacity, at the time Morton
Sound production commenced - Beaufort Sea discoveries may extend the
period of full capacity of the pipeline).
Similarly, a western Alaska gas pipeline to take Norton Sound gas to theNorthwest pipeli,ne near Fairbanks may not be economically feasible given
the estimated Norton Sound gas resources even assuming that the Northwest
pipeline can accommodate additional throughput.
Our analysis, therefore, assumes tanker export of crude, and liquefaction
of natural gas and tanker shipment to the lower 48. Consequently, an
important part of the scenario analysis is the identification of suitable
shore sites for crude oil terminals and LNG plants along with support
bases for exploration, field construction, and field operation activities.
The requirements for shore facilities in support of offshore petroleum
development are extremely varied. It is probably reasonable to assume
that if the economics are favorable most adverse siting conditions could
D-1
be overcome. For example, vessel draft requirements can be accommodated
by dredging, extension of piers and offshore loading; the Drift River
oil terminal is an example of the latter. Land can be leveled for the
construction of facilities; construction of Alyeska’s Valdez terminal
involved considerable earth and rock excavation. Breakwaters can be con-
structed to provide sheltered waters. Marine and overland pipelines can be
extended to accommodate facility siting. It would be desirable to have road
access to marine oil terminal and LNG plants (the principal onshore petroleum
facilities that may be required by Norton Sound OCS development) but it is
also possible to build these facilities without this transportation con-
venience and rely more heavily on air and sea transport. N o r t o n S o u n d ’ s
particular constraints to siting include hydrographic limitations, sea ice,
and onshore permafrost.
While the most economical shore facility site would probably be that with
none of the limitations cited above, facility siting in many cases is a
compromise between various technical criteria and environmental and socio-
economic suitability, This analysis, however, focuses on the technical
feasibility of sites while Section 11.3 of Appendix C comments on the en-
vironmental sensitivity of petroleum development in Norton Sound (subsequent
studies of the Alaska OCS Socioeconomic program will evaluate the socio-
economic impacts of various sites).
11. Previous Studies
In response to pending D-2 legislation, the Federal-State Land Use Planning
Commission for Alaska contracted for the feasibility assessment for 29 poten-
tial port sites in Alaska that could be used to load crude oil (Engineering
Computer Optecnomics, Inc., 1977). It was assumed for that study that the
trestle lengths would be limited to 1,830 meters (6,000 feet). This restric-
tion, however practical, severely limits the size of tankers that can be
accommodated at pierside for most of the Bering/Norton area. Nome and Cape
Darby were both evaluated as possible ports; with Nome receiving a slightly
higher rating in overall economics. However, several environmental and
technical considerations which could significantly impact port development
economics were not evaluated in a relative sense. Differences among these
●
●
*
*oD-2 ●
.factors could become important when other differences are small. While
recognizing the magnitude of the problem, we believe that a comparative cost
analysis should consider in more depth the technical components than were
done in that study.
An in-depth report prepared for the U.S. Department of Commerce by the
Arctic Institute of North America (1973) investigated several possible
terminal port sites within the Bering/Norton study area. Only one (Lost
River) was given a high priority rating while the sites along the north
coast of Norton sound were rated as medium priority. In all cases, the
tanker draft requirements were considerably less than those envisaged for
the present study, but certainly within the scheme of available options
for the transshipment of crude out of the Bering/Norton area. That report
stated that an additional advantage of a port at the Lost River location is
that it could be used as a multipurpose facility for transporting minerals as
well as oil.
Many unknowns concerning construction in the Arctic were addressed
the Institute’s report (some of which have been
the construction of the trans-Alaska pipeline).
some of the uncertainties, that study suggested
experimental port.
adequately answeredAs an approach to ~
n
by
nswering
thq actual construction of an
Distance to deep water is a very real concern for the development of marine
oil terminals and liquefied natural gas (LNG) plants in the present study
area. It appears, and this seems to be borne out by the previous studies,
that for very deep-draft tankers 18 to 21 meters (60 to 70 feet) offshore
loading must be provided. The 1977 study addressed the economics of a
single-point-mooring/storage tanker possibility. Singlepoint-moorings with
onshore storage were considered by the 1973 study. These systems would have
the capability of’ being withdrawn below the level of the ice when not in use.
It also mentioned the possibility of a rigid platform for offshore loading.
A study prepared for the Maritime Administration (Global Marine Engineering
Company, 1978) assessed the economic feasibility of various transportation
D-3
systems. For that study a sea-island pier was envisaged. That stricture
was composed of standard breasting dolphins and loading facilities but
was connected to shore via a buried pipeline rather than with a trestle.
These latter two systems probably would prove more reliable.
Suitable sites for the placement of onshore petroleum facilities are limited ●
in the Bering/Norton area. The primary restriction which results in the
elimination of most locations is water depth. Marine terminals require
depths adequate to service tankers with drafts of about 18 meters (60 feet).
To accommodate the vessels in most of the Bering/Norton region would require
extremely long trestles, extensive dredging, or a system which employ an
offshore loading principle. Most of the lease area close to the Yukon delta
region can be eliminated because of this restriction. Also excluded are the
eastern portions of Norton Sound and most of the south and east coasts of the
Seward Peninsula, including the naturally sheltered Port Clarence. However,
even at those sites where depth allows their consideration as viable choices,
the loading facilities that will need to be built must be protected from
severe ice loading. As was demonstrated in Appendix C, Section 11.1
(Oceanography), there is diverse opinion as to the pature of the ice regime
in this area. This apparent data gap will need to be filled prior to petro-
leum development in the area.
In this siting study, it is assumed that major ice problems are within the
state of technology and that the required engineering is economically viable.
The sites that are considered herein were selected initially because.: (1)
they best conform to the depth limitation, and (2) they are strategically
located to best accommodate finds in any portion of the lease area. For
example, locations on both St. Lawrence Island and in the Lost River area
have been included because, even though these sites have serious drawbacks on
several other grounds, they do possess reasonable water depths and are
situated in areas”that might make them the only ones practical given certain
discovery locations.
*
*D-4
III . Facility Siting Requirements
Following is a brief discussion of the facilities and their siting re-
quirements (see Table D-l). This is then followed by a description of
the sites that have been selected.
111.1 Temporary Service Base
These form the real vanguard of the petroleum complex. Such facilities
service the exploration, field delineation, and operation phases. At the
exploration stage of development, the industry generally attempts to moderate
extensive financial commitment by, when, and where possible using existing
facilities. Distances to the marine activities often dictate this approach.
In remote areas, such as the Bering/Norton region, existing facilities are
extremely limited. A few airports are scattered throughout the area but
all, with the possible exception of Nome, would require extensive work to
become suitable for continual use by large, heavily-laden aircraft. Docks
and harbors would have to be built and in most of the sites housing and
associated services would have to be provided. It appears that two options
are presently available, both of which have severe limitations. The first is
that supply and service to the offshore activities could be handled out of
the Aleutian Islands (see discussion in Section IV,7). However, this repre-
sents an extremely distant area with turn-around times to be measured in days
rather than hours. The other possibility might be to use large barges or
semi-submersibles as service bases. These could be located essentially
anywhere within the lease area and provide the necessary support to the ‘drill
rigs. To our knowledge this has not been attempted but appears, at this
time, to be a likely option.
111.2 Permanent Service Bases
As the offshore activities intensify, the services provided by a temporary
service base must be expanded and/or relocated. A more per-rnanent base,better able to support this increased level of activity, may be required.
Several rigs may have to be serviced, communication and transportation links1 with less remote areas improved, and greater storage provided. Table D-1
D-5
TABLE 0-1
SUMMARY OF PETROLEUM FACILITY SITING REQUIREMENTS
Facility
Crude Oil Terminal’
Smal l-Medium (<250,000 bd)
Large (500,000 bd)
Very Large (<l ,000,000 bd)
LNG Plant’
(400 MMCFD)
( 1,000 MMCFO)
Construct ion Support Base’
LandHectares( A c r e s )
(:)138
(:::)
(740)
k(;)
(200)
16-30(40-75)
WiHarbor
Entrance
15-23(50-75)
13-16(;;:::)
( 4 3 - 5 4 )
9.1(30)
r Depths -
Channel
14-20(46-66)
11-14(;;-::)
(37:46)
L(:0)
fw+.!Basin
13-19(42-61 )
10-13(;::::)
(34-42)
(:0)
L
-
Area
12-18(40-58)
10-12(;:-;:)
(33:40)
5.5(18)
No. ofJetties/Berths
1
2-3
3-4
1
2
5-1o
Jetty/Dock
FrontageMeters(Feet )
457(1500)
914-1371(3000-4500)1371-1829
(4500-6000)
304- 610(1000-2000)
304- 610( 1000-2000)
14i nimumTurningBasinWidth
Meters_.!@#L_
1220(;00:)
(f:y:)
(4000)
1220( 4000)
304- 457[1000-1500
Corrnents
Required space inturning basin canbe reduced substan-tiality should tugassisted dockingand departures berequi red
In addition tothroughput, sizeof plant will alsodepend on amountof conditioningrequired for gas
Requires additional61 m of dock spacefor each pipelayingactivity beingconducted simultane-ously and each ad-ditional 4 platforminstallation peryear
‘ Trainer. Scott and Cairns. 1976: Sullom Voe Environmental Advisory GrouD. 1976: Cook Inlet Pioeline Co. . 1978: NER8C. 1976: State of Alaska, 1978.‘ Dames &-Moore, 1974; State of Alaska, 1978.
. .
‘ Alaska Consultants, 1976.
● ● ● ● ●o
●
lists the land and depth requirements for such a facility. At times,
permanent service bases are simply extensions of a temporary facility, but
more often they require a completely separate location in greater proximity
to field development.
111.3 Construction Support Base
platform installations and pipelaying operations are generally supported
from a construction support base. Table D-1 lists the depth and land re-
quirements for such a facility, assuming it would be land-based. The
minimum of 61 meters (200 feet) of berthing space must be increased by
another 61 meters (200 feet) for each additional pipeline spread that is
operating coincidental with other pipelaying activities from the base.
Similarly, increased space would be necessary for every additional platform
installation per season.
Seasonal constraints on pipelaying and platform installations are extremely
severe in the Bering/Norton Basin. Coupled with the lack of facilities and
the expense of constructing them may lead to the use of a floating-type
structure to support construction operations. These have already been
mentioned as possible substitutes for land-based temporary service bases.
Alternately, some construction support facilities, such as pipe storage and
pipe coating, may utilize an Aleutian Island site even though resupply
turnaround would be significantly lengthened.
111.4 Marine Oil Terminal
The crude product will ultimately be transported to a centralized point
for transshipment. Here stabilization of the crude may be completed, LPG
recovered, tanker ballast water treated, and storagg provided. Marine
oil terminals serve these purposes and represent large investments. The
number and size of these facilities are dictated primarily by throughput
capacity and discovery location.
The scenarios for the Bering/Norton area address several throughput and1 field location options. Should two major finds occur sufficiently dis-
tant frcm each other, two terminals may be required. The land and depth
D-7
requirements for marine terminals are shown on Table D-1. Figure D-1
shows a plot of harbor depth and vessel draft requirements as a function
of dead-weight tonnage. A study performed by the Global Marine Engineering
Company (1978) for the U.S. Maritime Administration indicated that for
ice-strengthened tankers the increase in draft to provide the same capacity
as conventional tankers would be from 2-4 percent depending on vessel size.
Most of a terminal’s land requirements are used for crude oil storage.
It is likely that in such a hostile environment as the Bering/Norton Basin,
weather could hamper the progress of crude oil loading and vessels in transit
more than in any other area heretofore developed. This greater uncertainty
about arrivals and departures might require added space for additional
storage.
Trestles are a possibility for transporting the crude from,the terminal to
deep water for loading. Offshore loading, using a marine pipeline from
shore, is also a possibility, but it would seem that the severe ice con-
ditions would preclude the use of buoy-type (e.g. Drift River) or compliant
structures. Steel platforms built to similar ice-resisting specifications as
drilling and production platforms might well serve as an alternative.
111.5 Liquefied NaturaJ Gas Plants
Should dry gas in economic quantities be found, an LNG plant will be re-
quired. The alternatives to liquefying the natural gas are flaring, direct
distribution to consumers or as feedstock for petrochemical feedstock within
the State. Flaring is generally not permitted, there is no market for direct
distribution, and a petrochemical plant in this part of Alaska is highly
unlikely. Therefore, the scenarios postulated herein assume conversion of
non-associated gas to LNG and transport out of Alaska.
●
*
Table D-1 also gives the major siting requirements for an LNG plant. As
wi,th the marine terminal, land requirements are extremely sensitive to
plant capacity. Land requirements for an LNG plant vary according to
type of gas and quantity of gas to be processed. A plant with a total
D-8
I
24.31(80)
21.34(70)
18.2!(60)
15.24(50)
9.14(30)
6.10(20)
3.05(lo)’
.
0 1 I I ! I102,000
I
(100,000)204,000
(200,000)306,000
METRIc TONS(300,000)
o
(DEAD WEIGHT TONS)
FIGURE D-1R E Q U I R E D DEPTHS FOR TANKERS AT MAilNE TERMINAL
n.
vaporization capacity of 400 MMcfd of gas would require about 24 hectares
(60 acres) of land with an all-weather wharfage. The site should be rela-
tively flat lying, with good drainage. Facilities at the site will include
administration facilities, shop and warehouse, utilities, water filtration
facilities, sanitary facilities, control house, compressor stations, and a
gate house. A plant processing 400 MMcfd would probably require LNG tanks
with a total capacity of 1.1 million barrels. Most of the space utilized at
an LNG plant is for safety, and storage.
Iv. Potential Shore Facility Sites in the Norton Basin Lease Sale Area
IV.1 General
Given the constraints outlined in the previous section, five technically
feasible sites have been identified in the Bering/Norton Basin:
e Nome
o Cape None
o Cape Darby
@ Northwest Cape
o Lost River
The first three are located on the northern coast of Norton Sound, Northeast
Cape is on St. Lawrence Island, and Lost River is west-northwest of Port
Clarence. Both Nome and Cape Nome are close to existing transportation and
social facilities and while such infrastructure is beneficial, it is not
crucial; on-site services and accommodations can be provided.
IV.2 Nome
9
Sufficient water depths to accommodate deep-draft tankers lie in excess
of 4.8 km (3 miles) from shore in the direct vicinity of the City of Nome.
Owing to the possibility of extreme ice-loading conditions, this distance
appears excessive to permit the construction of trestle-pier-type facilities
along side of which tankers could receive oil and LNG from shore. The
D-ICI *
1 preponderance of the land nearshore on the
Peninsula is low-lying and storm surges of
Coastal activity is quite extensive. Even
south coast of the Seward
several meters have occurred.
shore-based service bases would
require approximately 1 km (0.6 mile) or more of trestle to reach water
sufficiently deep to accommodate vessels of 5 to 6 meter (17 to 20 foot)
drafts. Tide ranges are significantly less than 1 meter (3.3 feet) along
this coast with flood currents of less than 51 cm/sec (1 knot) being directed
to the east and ebb currents to the west. Because of the importance of Nome
to any type of development in the Bering/Norton region, this site might be
selected to locate onshore facilities provided the distance to the finds did
not favor other sites.
At present, the city of Nome has a small boat harbQr at the mouth of the
Snake River. It has a turning basin 76.2 meters (250 feet) wide and 183
meters (600 feet) long. A 23 meter- (75 feet-) wide entrance channel con-
nects the harbor to Norton Sound. The depth of the turning basin and
entrance is maintained to a depth of minus 2.5 meters (8 feet) below mean
lower low water (MLLM) by annual dredging. The basin is subjected to sedi-
mentation from both the Snake River and material transported into the harbor
from the sound.
To use this facility as a support/construction service base would require a
minimum depth of approximately 6.1 meters (20 feet) which would carry out to
deeper water. Such a condition would require an extensive amount of dredging
w h i c h p r o b a b l y w o u l d n o t b e e c o n o m i c a l l y f e a s i b l e .
However, another concept to accommodate vessels with similar draft require-
ments was explored by Gute & Nottingham (1974) in a feasibility study pre-
pared for the Alaska Department of Public Works. The schemes described in
that report considered gravel causeways out to a dock at the appropriate
water depth. They found that approximately ’a 1000-meter causeway would be
required at Nome and a causeway length of less than 500 meters would be
necessary at Cape Nome. Mainly for this reason, but also for others out-lined in the report, they concluded that the Cape Nome site would be more
)appropriate for development than adjacent to the city.
II-11
The availability of sufficient amount of open space to construct facilities
should not be an overriding consideration at either Nome of Cape Nome.
In considering more extensive facility development such as marine terminals
or LNG plants, the depth requirements are even mor~~ demanding being ap-
proximately 19 meters (62 feet) below MLLW. A causeway built to this depth ewould more than double their length. Perhaps an of”fshore loading facility
could be used with pipelines buried below the deptl of ice scour. This would
require a well-insulated pipelinein the case of LhG transport, and we do not
have data on the state-of-the-art of such an operation.
IV.3 Cape Nome
Located approximately 16 km (10 miles) east of Nome, Cape Nome, is perhaps
closer to deep water than Nome by approximately 1.5 km
graphy in this area is somewhat higher than around ,Nome
developed at Cape Nome could utilize the infrastructure
city. Suitable land for potential facilities locations
1 mile). The topo-
and facilities
provided at the
ies immediately to
the west of Cape Nome itself (Cape Nome itself is a prominent headland with
high cliffs). Currents, winds, and waves and tidal range are essentially the
same as those found at Nome. Because of its location relative to the City
and the shorter distance to deep water, this area should be considered as a
prime candidate for the location of onshore petroleilm facilities.
IV.4 Cape Darby
Lying further to the east approximately 130 km (80 miles) from Nome is Cape
Darby, on the east side of the entrance to Golovnin. Bay. Water depths of
approximately 18 meters (60 feet) occur almost at the shoreline in CapeDarby but these are not connected to the deep water on the western side of
Norton Sound. Depths of less than 18 meters (60 feet) are encountered
between these two deep water regions. The topography is high in this area
and steep cliffs border the coastline. Being further toward the inner Sound,ice coverage occurs somewhat longer than at Nome and Cape Nome. The prin.
cipal attraction of this area is that with a slight reduction in tanker
draft, development at Cape Darby would preclude construction of a lengthy
e
eoD-12
\“9
pier system or the need for offshore loading systems. A possible disad-
vantage of Cape Darby is Its location near Golovnin Bay. This bay has been
identified as a biologically important area which may suffer severely from
either catastrophic or accumulated oil spills.
IV.5 Northeast Cape (St. Lawrence Island~
Most of the land within 2.5 to 3.5 km (1.5 to 2.2 miles) of the shoreline is
of low elevation, probably composed primarily of tundra. Judging by the
continuity of the barrier islands, it appears that the coastal processes are
extremely active. A site probably having a sufficient amount of high ground
can be found directly on Northeast Cape. Offshore of this site it appears
that sufficiently deep water occurs approximately 3.5 km (2.2 miles) off-
shore. Since the prevailing winds are from the southwest during the ice-free
period, this area should be relatively protected from storm surges and
intense wave activity. There is essentially no infrastructure near this site
(Nome is 215 km [133 miles] to the northeast). It is ice-free approximately
six months of the year.
IV.6 Lost River
The final site considered in this analysis is near the mouth of Lost River
lying within the northern portion of the proposed lease area. Its isolated
location probably would allow it to be a viable site only “
within close proximity. A possible advantage to this site
interest shown over the last few years in developing it as
port. This has been suggested principally because of its
to mineral-rich areas onshore on the Seward Peninsula.
f the field(s) was
is the continued
a multipurpose
ocation relative
Deep water lies approximately 2.5 km (1.5 miles) off the shoreline. The
shore itself appears to be quite active in terms of sediment transport asindicated by the nearby barrier islands and the spit at the mouth of Port
Clarence. Much of the area is low-lying and storm surge could represent a
possible hazard. Of the areas selected, Lost River has ice break-up later in
the summer and freeze-up earlier in the fall.)
D-13
IV.7 The Role of an Aleutian Island Support Base in Norton BasinPetroleum Development
The lack of suitable port sites and the presence of seasonal ice make logis-
tics support for offshore drilling, construction and production operations a
major problem for petroleum development in Norton Sound. 9
In the scenarios described in Chapters 5.0, 6.0, 7.0 and 8.0, the possibility
has been mentioned of the use of an Aleutian Island port in support of Norton
Basin petroleum development activities. For manpower estimation, however, we a
made the assumption of locally provided support facilities with the expansion
of Nome and/or construction of a new support base in the Cape Nome area
following significant discoveries; exploration support would be provided
by existing facilities at Nome combined with the use of storage barges and
vessels moored in Norton Sound. This is, of course, only one possible
scenario.
*
Extensive use of a rear Aleutian Island support base for exploration and
field construct~on (platform installation, pipe-laylng, etc.) is also a
reasonable possibility. The development of such a facility is better con-
sidered, however, in the context of the strategic pc}sition of the Aleution
Islands with respect to several Bering Sea lease sale areas in addition to
Norton Sound including the St. George Basin, North Aleutian Shelf, and
Navarin Basin sales which are currently scheduled f~r 1982, 1983, and 1984,
respectively. If major
they are more likely to
sales than Norton alone
and North Aleutian).
facilities are developed in the Aleutian Islands,
be developed in response to the needs of several
especially for those in close proximity (St. George*
The advantages of.the Aleutian Islands with respect providing support facili-
ties for Bering Sea petroleum development include:
o Existing deepwater anchorages, some with infrastructure, such asDutch Harbor;
c Numerous deepwater anchorages, including several potential un-
developed sites in the Dutch Harbor area itself;
s Ice-free coastline.
II-14 ●
The principal disadvantage of an Aleutian Island support base with respect to
Norton Sound is “that Dutch Harbor, for example, is about 1207 kilometers (750
miles) from Nome; this distance represents about 65 hours sailing time (one
way) for a typical supply boat cruising at 10 knots. Regular resupply of a
platform or pipeline barge would, therefore, tie up a considerable number of
boats and make resupply an abnormally expensive operation. Thus one of the
major criteria for a supply (service) base site--proximity to offshore
fields--is lacking in Aleutian sites with respect to Norton Sound activities.
More likely, however, are somewhat different roles than regular direct
resupply and service of offshore platforms, pipelirie activities, etc. It may
be that an Aleutian port wouJd serve as a transshipment point for oil field
exploration and construction supplies destined for Norton Sound; until
adequate draft facilities were available in the Nome area, supplies could be
transferred form large freighters in transit from the lower 48 to shallower
draft vessels for transport to Norton Sound. Another possible function of an
Aleutian support base would be an extension of the transshipment facility
role whereby extensive storage of materials [destined for Norton Sound)
brought in by year-round traffic from the lower 48 would be provided. Such
material stockpiles would permit optimal use of the short summer weather
window in Norton Sound.
It is difficult to predict the role(s) of an Aleutian support base related
to Norton Sound with respect to the different phases of petroleum develop-
ment (exploration, development, production). Support during construction
(development) activities in the roles indicated above appears to be more
likely than regular resupply functions required by exploration and production
activities. Another important role for an Aleutian port may be as an oil
transshipment terminal where oil is transformed from ice-reinforced or ice-
breaking tankers to conventions? tankers for shipment to the U.S. West Coast
as postulated in a report by Global Marine Engineering Company (1978). In
terms all the Bering lease sales scheduled for the early mid-1980’s, one or
more Aleutian port sites will serve as support bases, transshipment facili-
ties, crude oil terminals, and LNG plants. Thus the Aleutian Islands are
probably destined to provide a variety of important facilities in the support
and development of Bering Sea OCS oil and gas resources even if their role) relative to Norton Sound was somewhat more limited than the other lease
areas.
D-15
IV.8 Results
Selection of these five sites has been made on the basis of limited oceano-
graphic and coastal information; the Bering/Norton region is far removed from
areas of active scientific and engineering study. The possibility of sign-
ificant petroleum finds could well prompt more environmental studies in-
cluding port site evaluations that would more clearly define potential impacts.
The entire Norton Sound region has land-fast ice within a few kilometers of
the shore during the winter and, except for Cape Darby, is quite distant from
deep water. Nome, Cape Nome, and the Lost River sites are probably prone to
periodic storm surges. Northeast Cape (St. Lawrence Island), Lost River, and 9
Cape Darby are isolated relative to existing infrastructure. Cape Nome lies
on higher ground and is closer to deep water than Nome. These factors,
although certainly not sufficiently complete to make an indisputable priority
selection, do suggest the following ranking in order of decreasing technical
desirability:
Q Cape Nome
e Nome
e Northeast Cape
* Cape Darby
6 Lost River
The order of this list could be completely altered depending on the location
and magnitude of any petroleum finds. That is, the Lost River site could
vault to the top of this list should it be substantially closer to the
developing field.
As was discussed in the siting requirements, none of the sites would repre-
sent ideal areas for
would be constructed
an Aleutian base, or
Sound.
exploration bases. It is probable that no such base
in the Bering/Norton area; such support would come from
converted barges or drilling platforms towed into Norton
●
APPENDIX E
APPENDIX E
EMPLOYMENT
I. Introduction
This section provides a general introduction to
requirements for offshore petroleum development
th~ subject of manpower
as well as the defini-
tions, assumptions, and methods used to generate the manpower estimates
for each scenario described in Chapters 5.0, 6.0, 7.0, and 8.0. Refer
to these chapters for the results of the analysis described in this
section.
11. Three Phases of Petroleum Exploitation
Exploitation of a petroleum reserve involves three distinct phases of
activity -- exploration, development, and production. The exploration
phase encompasses seismic and related geophysical reconnaissance, wild-
cat drilling, and “step out” or delineation drilling to assess the size
and characteristics of a reservoir. The development phase involves
drilling the optimum number of production wells for the field (many
hundreds of wells are used to produce a large field) and construction
the equipment and pipelines nec~ssary to process the crude oil and
of
otransport it to a refinery orto tidewater for export. The production
phase involves the day-to-day operation and maintenance of the oil wells,
production equipment, and pipelines, and the workoser of wells later in
their producing life.
The three phases of petroleum exploitation overlap and all three may
occur simultaneously. Exploration for additional fields continues in
the vicinity of a newly discovered field as that field is developed and
put into production. On the North Slope, for example, where the Prudhoe
Bay field is in production, exploratory and delineati~n drilling will
continue for several more years. Development activity typically contin-
ues after the initial start-up of production. Operators need to start
production as soon as possible to begin to recover expenses of field
development (Milton, 1978). In the North Sea, for example, production
●o
E-1●
from some fields was initiated with temporary offshore loading systems
while development drilling continued and before underwater pipeline
construction began.
Local employment (1) created by each phase of the petroleum exploitation
process tends to have characteristic magnitude and attributes. For
example, exploratory work is not particularly labor intensive, and
wildcat crews come and go with drilling contractors. Local residents
are most likely to benefit indirectly from expenditur~s made for explora-
tion programs rather than from direct employment in the oil field. The
development phase creates the highest levels of employment locally, and
m u c h o f t h i s e m p l o y m e n t i s i n t h e c o n s t r u c t i o n a n d t r a n s p o r t a t i o n i n d u s -
t r i e s . L a b o r d i r e c t l y a s s o c i a t e d w i t h d r i l l i n g a n d i n s t a l l i n g c r u d e
processing equipment is highly skilled. Because of automation, the
production phase does not require a substantial workforce. This work-
force will include many experienced oil field operators recruited from
outside the area or transferred from other fields by the owner companies.
Figure E-1 depicts a very general and hypothetical temporal relationship
of the exploration, development, and production phases and the relative
magnitude of local employment created by
differ in their own development schedule
and transportation facilities.
each. Particular oil fields
and requirements for production
III . Manpower Utilization in an Arctic Environment
Although Norton Sound is technically a subarctic region (the entire area
is below the Arctic Circle), conditions there are generally similar to
(1) Local employment refers to employment at or near the petroleumreservoir. It does not include the manufacturing and constructionemployment created away frm the site, such as that involved wifh thebuilding of process equipment and offshore platforms, nor does it in-clude professional , administrative, and clerical work that occurs inregional headquarters (London and Aberdeen in the case of North Seafields and Anchorage in the case of Alaska fields, for example).
)
E-2
*
●
/-\
/\
/\
$-/$$ \
$ A*
/\Go
A&
/$’s \
\
PRODUCTION-o--w-mm m-EMP!,J2YMENT
YEAR I 2 3 4 5 6 7 B 9 10 II 12 13 [4 1!5 16
1EXPLORA?’ION IIEVELOPMENT PRODL!CTIOIUBEGINS BEGINS SEGINS
●
●
SOURCE: DAMES& MOORE
●
Figure E-1
LOCAL EMPLOYMENT’ CREATED SY THE THREE PHASES
OF PETROLEUM EXPLOITAT’10Nt A HYPOTHETICAL CASE ●
o
E-3 ●
those of true arctic environments from a point of view of labor produc-
tivity and support. The area is remote; freezing temperatures and
ice-bound water prevail for much of the year. Generalizations about
manpower utilization in arctic environments certainly apply to Norton
Sound.
111.1 Expense of Labor in the Arctic
Every effort is made to reduce the amount of manpovler required for
construction and operation of the facilities in the Arctic because of its
very high cost. The high cost of labor in the Arctic is not simply a
matter of higher than usual wage rates that must be paid to workers in a
remote, inhospitable environment; more significantly, it is because labor
in cold regions tends to be extremely inefficient and creates a tremendous
burden of support. Efficiency of manual labor in the arctic is reduced
by the long hours worked each day (productivity decreases sharply after 8
hours of effort) and the long number of days worked consecutively without .
a break (efficiency drops as the length of rotation increases). Manual
labor performed out of doors during the long periods of cold is slowed
greatly by temperature and darkness. It has been estimated that the
cumulative affect of these factors can reduce the manual productivity of
a worker 250 percent in the Arctic (Chandler, 1978). Indoor work in
heated, well lighted buildings in the Arctic and summer out door work,
does not, of course, suffer the massive inefficiencies of out door work
in the cold and darkness. Overall labor inefficiency means that more
manpower is required in the Arctic because either the rate of progress
for regular crews is slower than normal or the lower productivity of
workers must be offset by
A workforce in the arctic
support: providing food,
more workers.
is also expensive because it requires enormous
shelter, and transportation for workers is
complicated by distance from urban centers and the long periods of
extreme ccld and darkness that prevail much of the year. A preliminary
design-study by the Department of Public Works Canada of an arctic marine
terminal at Herchel Island (Public Works of Canada, 1972) notes that
support operations in the Arctic require a signif cant?y greater effort
E-4
than less severe environments. The study sites the Canadians experience
on the Shoran Survey conducted between 1946 and 1957. These surveys were
carried out in four distinctly different climatic zones. It was foundthat in “normally habitable” areas of the subarctic, four tons of supplies
were required per man year; elsewhere south of the treeline, eight tons
per man year; between the treeline and the arctic rflainland coastline in
northern Labrador and Quebec and southern Baffin Island, 12 tons per
man year; in the Arctic Basin and the Archipelago, 16 tons per man year.
Although sealift was used to supply as much of this material as possible,
a considerable amount of air freighting was also required. The report
stated that placing supplies in the field by sealift cost approximately
$0.06 per pound in constrast to $0.50 per pound by airlift (while these
costs are no longer applicable, the magnitude of the differential is
still representative).
111.2 Labor Saving Techniques
In discussions with industry representatives about the likely technology
and construction methods to be used in Norton Sound, they have made it
clear that industry will strive to keep field manpower requirements as
low as possible through the maximum use of prefabrication and modular
construction. Other labor saving techniques may also be available.
For example, it is interesting to note that Canadian Marine Drilling,
Ltd., (C.anmar), is using an ocean-going bulk carrier as a floating sup-
ply base for its northern Beaufort Sea exploratory dril?ing program,
and that Imperial Oil is presently using a floating operation headquarters
for its artificial island construction program in the southern Beaufort
Sea. These floating bases reduce the scale of activity as well as the
socioeconomic impact of temporary onshore supply bases.
Initially developed for small scale applications, the modular approach to
construction has now been broadened to very large projects. In describing
a recent use of prefabricated
stantial gas plant in Mexico,
advantages of the technique:
process equipment modules to build a sub-
Oil and Gas Journal noted these important
●
*
E-5 ●
Statistics have proven that construction labor is much moreefficient in fabrication centers than at typical field con-struction sites. More than one project is normally in p r o -gress simultaneously. Work loads can be leveled. Use offewer people means less-crowded conditions, which are moreefficient and safer.
Another economic advantage is that labor rates in fabrica-tion centers generally are lower tlian those required toattract labor to a remote plant site where craftsmen mustlive away from home. Since living in one location is pre-ferable to most workers, a larger labor force is availableand better craftsmen can be selected. Quality is improved(Oi 1 and Gas Journal, August 20, 1979).
The article also reported that the gas treatment plant was erected on
site in only three months, which was substantially shorter than a con-
ventionally built plant. These savings occurred in a temperate zone, so
they would be multiplied at a cold region site.
Modular construction techniques are well known in Alaska. Prefabricated
modular oil and gas processing components have been used extensively in
the development of offshore petroleum resources in Cook Inlet. Large
prefabricated units of processing equipment were also used in the devel-
opment of the Prudhoe Bay field. If oil fields are developed in Norton
Sound, the modular approach to construction will be used extensively,
perhaps in ways that are now little more than design concepts. For
example a very likely application of the modular approach is the construe-
tion of a LNG plant.
111.3 Prefabricated, Barge-Mounted LNG Plant
It seems likely that if an LNG Plant is required for gas productionin Norton Sound, it would be built on a series of barges which would be
towed to a protected shore site, post-tensioned together, and moored or
sunk on a
extremely
excess of
) crete LNG
prepared bed for operation. Conventional LNG plants are
labor intensive to build on site; large plants have required in
5,000 workers (Pipeline and Gas Journal, 1977). Floating con-
plants were first proposed by Global Marine for offshore gasfields that cou d not support the high cost of long submarine pipelines
E-6
to shore and that were remote from industrial fabrication yards. Engi-
neering and design of barge-mounted LNG plants has progressed to the
point that this technique seems feasible for gas fields of modest size.
An arctic application of the concept of a barge-mounted LNG plant is
currently planned by Petro-Canada to produce gas reserves of the high
arctic islands. This scheme involves three ice-strengthened barges that
will float in specially constructed land-locked tical slips. A concrete
barge mounted LPG plant was recently fabricated in Tacoma by Concrete
Technology, Inc. for ARCO Indonesia. The pre-stressed concrete barge
measured 142 x 41 x 18 meters (465 feet x 135 feet x 58 feet), and had a
capacity of 65,000 tons. The barge-mounted plant has towed~o an offshore
site in the Java Sea.
For purposes of this report, it is assumed that a prefabricated, floating,
shore-based, barge-mounted LNG plant would be used to exploit gas resources
in Norton Sound. This assumption lowers considerably the projected
development phase manpower requirements from levels that would be created
by conventional onsite construction of a LNG plant. In this case, field
labor would be limited to that necessary for site preparation, construction
of a marine loading dock, an airfield, roadway, and shore facilities
including a dormitory-type camp for construction and operational personnel
(some of this infra-structure might be shared with ]ther facilities).
This construction would probably require two season; and involve a peak
work force of some 300 people and a monthly average work force of about
150 people for a large plant. These are, of course, no more than educated
guesses of the level of effort required, as there is no previous experience
with this technology. Actual manpower requirements would depend upon the
capacity of the plant, the number of loading berths, and the length of
the loading jetty, the availability of ground water, location and geomor-
phology of the site, the extent of which support infra,-structure was
shared and so on:
111.4 Labor Intensive Arctic Construction
Modularization of equipment can greatly reduce field manpower re-
quirements and speed installation of offshore platforms, onshore oil
●
●
9
E-7
and gas treatment plants, pump and compressor stations, and other
facilities that process oil and gas. However, the labor saving modular
approach to construction is not applicable to much of the effort required
to build pipelines or a marine terminal. Conventional construction
techniques must be used for these essential facilities, and in the
Arctic, conventional techniques demand more manpower than required in
less severe environments (~)c This is because of the Iow productivity
of manual labor for much of the year, and because construction is gener-
ally more difficult in the presence of permafrost and sea ice.
The experience of the trans-Alaska pipeline has shown that construction
of crude oil pipelines in cold regions requires different techniques and
significantly more manpower than in temperate zones. Pipe can be
burled only in frost stable soil (gravel, sand, or rock), and ditching
for large diameter pipe requires drilling, blasting, and removal of
spoil by large hydraulic backhoes rather than by one pass of a trenching
machine. Select backfill may be required, which means mining, processing,
and hauling large quantities of crushed rock or gravel. In permafrost
zones the pipe must be built above ground and insulated. Work pads and
roads require insulation and considerable gravel overlay. Much work must
be done in the winter (for example, river crossings) when labor ineffiency
is greatest..
There are only limited opportunities for use of the labor saving
modular approach to construction of a marine terminal. Metering and
pumping equipment, power generators, and vapor recovery facilities can
be prefabricated and shipped to the site as skid-mounted modules. .
However, construction of crude oil storage tanks, piping, ballast
treatment tanks and facilities, and site preparation are unavoidably
(1) This may not be true of offshore pipelaying in Norton Sound.While special construction techniques may be necessary at landfallto protect buried pipe from ice scour, the process will be a conven-tional one that uses a standard laybarge spread during the summer,open-water season.
E-8
labor intensive. Manpower
berths may be reduced by a
buoys, tressels, and other
terminal will also tend to
requirements for construction of tanker
design that utilizes prefabricated floatingcomponents, but this segment of the marine
be labor intensive.
111.5 Construction of Artificial Islands
It is possible that man-made sand or gravel islands may be used forexploratory drilling near shore and for production platforms if commer-
cial discoveries are made in shallow water (artificial islands are
discussed in Appendix C). Estimating the manpower needed to construct
these items is very difficult because several factcrs effect the amount
of equipment and length of time required for construction. These factors
are:
9 Size of the island.
* Depth of the water.
● Proximity of suitable fill to island site.
e Clown-time caused by weather and equipment failure.
@ Construction technique used (reinforced sandbag, artificial
beach, etc.).
The only experience with these islands that can serve as the basis for
estimating manpower requirements is that of Imperial Oil, Ltd., which has
built over a dozen artificial sand islands in the Beaufort Sea. These
islands have been used only as exploratory drilling pads. Thus, they are
much smaller and less permanent than islands that would be necessary
for production purposes.
Imperial Oil is presently (summer 1979) building the largest of its
artificial islands -- a structure requiring from 3.5 million cubic
meters (4.6 million cubic yards) of fill in 20 meters (64 feet) of water.
The construction spread consists of:.
* One 24-inch cutter dredge.
9
●o●
One 34-inch stationary suction dredge.
One 20-inch stationary suction dredge.
Five 2,000-cubic yard bottom dump barges.
Three 300-cubic yard bottom dump barges.
Four 1,500-h.p. tugs.
TWO 600-hop. tugs.
One floating crane.
Four 6-cubic yard clamshell cranes on spudded barges. Barging
loading pontoon, sandbagging machines, and float’
One 320-foot barge fitted with 70-man camp, reps
communications, rand office space.
ng pipelines.
r shop,
Several other barges, launches, and auxillary equipment.
Onshore Imperial Oil has a supply base at the village of Tuktoyaktuk,
which is also the supply base of Canadi’an Marine Drilling, Ltd. (Canadian
Marine Drilling, Ltd. also uses an ocean-going bulk carrier as a floating
supply base.) P e r s o n n e l a t t h e s u p p l y b a s e p r i m a r i l y h a n d l e fuel and
material. Operations headquarters, communications equipment, repair
shop, helicopter crews, and transient personnel are housed offshore
the floating camp located at the work site.
Imperial Oil’s 3.5 million cubic meter island will take two seasons
of approximately 60 days each to build. This schedule will require
in
an
average production rate of 1,215 cubic meters per hour (1,215 x 24 x 60 x
2 = 3,499,200). Last year the largest dredge (“Beaver McKenzie”) dredged
i only 44 of the actual 66 days that it was on site. During that time, it
pumped fill at an average hourly rate of 11,036 cubic meters per hour.
Non-productive time was caused by mechanical failure (18 days) and
weather (4 days).
Rate of progress of the suction dredges depends upon the characteristics
of the fill and other factors. A significantly faster rate of production
was obtained on another island (Arnak), where at 1.5 million cubic meters
of sand was placed in 36 days (an average hourly production rate of over
1,700 cubic meters per hour).
In the middle of the current season, with work progressing on the largest
of the islands to date, Imperial Oil has approximately 65 men offshore
and about 90 men in the supply base camp at Tuk (this camp has quarters
for 120 men) . The rotation schedule varies somewhat among contractors
but most employees work 28 days and take 10 days off. This is a rotation
factor of 1.35, so the total work force at mid season is in the neighbor-
hood of 210 people. During mobilization and demobilization more manpower
is needed, but Imperial Oil reports that at no time has their been over
250 men on site (Butler, personal communication, August 10, 1979).
Labor force estimates for artificial islands in Nor<ton Sound have been
based on the foregoing information and additional information about
productivity found in technics? articles about these artificial islands
(for example, Garratt and Kry, 1978; Riley, 1975; a~d deJong, Stigter
and
Iv.
The
Steyn, 1975).
Additional Factors Effecting Labor Utilization
foregoing discussion has identified several factors that can effect
labor utilization the low productivity of labor in an arctic environment,
the extent of which prefabricated field development components are used
(a completely prefabricated LNG plant mounted on barges would greatly
reduce field labor requirements), availability of sand and gravel (ex-
ploration for and evaluation of subsea borrow material could take a month
or more), and weather. Several other factors also influence labor
utilization.
●
●
●o
●E-l]
One such factor that can influence the utilization of manpower is the
construction schedule. To a large degree, manpower can be substituted
for time. The decision to complete a project in two seasons instead of
three or in one season instead of two, would result in significantly more
labor than would be necessary with a more leisurely schedule. Also, it
i s n o t u n u s u a l f o r l a r g e , r e m o t e p r o j e c t s t o g e t b e h i n d s c h e d u l e ( s c h e d u l e
slippage) because of delays in material delivery or other unexpected
problems. In this case, more labor and equipment are added to theproject to speed up progress.
Manpower requirements may also be influenced by environmental stipula-
tions contained in State and federal leases, right-of-way agreements, and
permits for various construction activities. For example, stipulations
frequently require work in the arctic to be done in the winter in order
to protect damage to the tundra surface, interference with migrating
fish, etc., and winter work is the least productive for labor. Al SO ,
work may be suspended for environmental reasons during the open water
months when labor is most efficient.
Because of these and other variables, the manpower estimates in this
report are necessarily “best guesses”, and the actual manpower require-
ments of wildcat drilling, field development, and production”of oil in
Norton Sound could vary significantly from these estimates.
The manpower estimates shown in this report ”have not been rounded.They are unrounded so that they can be replicated by the reader. Use
of these numbers is not meant to impl y the level of accuracy of the
estimates.
IV.1 Manpower Estimates
Employment estimates for each scenario are generated by a computermodel developed specifically for this series of SX?ndriO studies.,
Exploration, field development, and production activii.ies have been
1 broken down into some 38 tasks, such as well drilling, terminal con-
struction, and platform maintenance, for which a reasonable estimate
E-12
of employment is possible. These general estimates are then matched
to the specific characteristics of the activities in each scenario.
Thus, the manpower estimates reflect such factors ,~s the number, type
and size of shore facilities, miles of onshore pipeline, the number
of development wells drilled, etc.
The OCS manpower model is described fully in $ectilln VII of this
Appendix.
V. Definitions
It is very important that terms are defined before describing the OCS
manpower model in detail. It is interesting to nol.e that although
several studies of 0(3 petroleum impact have now been made which in-
clude manpower estimates , neither a uniform set of definitions nor an
anticipated methodology has emerged (see, for example, NERBC, 1976).
Indeed, no attempt has been made in these to define such basic terms
as jobs and employment, and the methods used by thc!m to calculate(l). The fo l lowing def in i t ionsmanpower totals are opaque at best
tire used in the present study:
Job
●A job is a position, such as driller, roustabout, cr diver, rather
than a specific task or a person who performs the task or fills the
position.
Crew
A crew is a group of individuals who fill a set of jobs; a drilling
crew, for example, is a group of men who fill generally standardized
jobs necessary to accomplish the task of drilling a well. The term
crew is also used to refer to an estimated monthly shift labor force
(below).
(1) Because terms are not clear, manpdwer estimates are not readilycomparable. It is seldom evident, for example, if all crews are counted(most offshore work has more than one crew on site) and if off siteemployment is counted.
E-13
●
Estimated Shift Labor Force
This Is the average number of people employed per shift per month over
the life of the task. This estimate is made when several crews are
combined into a composite estimate of workforce size and/or when the
task for which an estimate is being made has a fluctuating monthly labor
force.
Shift
Shift refers to the hours worked by each crew eacf day; a normal shift
of offshore crews is 12 hours, and there are two shifts per day.
Rotation Factor
The rotation factor is defined as (1 +
crew worked for
would be two (1
rotation factor
14 days and then took 14 days off, the rotation factor+ 14—= 2); if a crew worked 28 days and took 14 off, the14would be 1.5 (1 +%= 1.5).
Total Employment
Total employment is the total number of men employed, and it is found by
the formula: jobs (crew size) x number of shifts/day x rotation factor;
for example, if a new task creates 10 positions, and two crews each work
connective 12-hour shifts, and the men work 14 days and take 7 off, then
total employment is 30 (10 x 2 x 1.5); thus, total employment includes
on site employment
On-site Employment
On-site employment
and off site employment.
is composed of the workmen who are not on leave ro-
tation, or two complete crews if two shifts are worked per day.
Off-site Employment)
Off-site employment is the group of employees
and not physically present at the work site.
E-14
who are on leave rotat on
Man-Months
A man-month is the employment of one man for month (1)* Thus, a man-
month is a measure of work that incorporates the element of duration of
work., This unit of measure is necessary to compare labor that varies in
length, Suppose a project had three components: component A employed
100 men for two months; component B employed 50 men for three months;
and component C employed 80 men for 12 mohths. To say the project re-
sulted in employment of 230 is to say little about it because there is
no indication of how long the employment lasted. Although component C
employed only 80 men, it was responsible for over four times as much
employment as component A, which employed 100 men for a shorter period(960 man-months vs. 200 man-months).
Measurement of employment in man-months avoids confusion between mart-
power requirements of a project and the total number of individuals who
are involved in it at one time or another over its life. Nhile some
workers will work steadily from the beginning to end, many will not,
(1) A month of employment (30 days) can involve very different amountsof work depending upon the hours worked during the week. Notice, forexample, that 8,0!30 man-hours of work are accomplished by 50 men working40 hours per week for four ~eeks, while 16,800 are accomplished by 50men working 84 hours per week (equivalent of seven 12-hour days) forfour weeks. Both cases might be said to represent 50 man-months ofemployment, since both involve 50 men for one month. However, one couldargue that the first case represents 50 man-months and the second roughlytwice that amount since men must have a reasonable amount of time torecuperate from their labor. In the case of the OCS employment at hand,men normally work long shifts for long periods, and then have a Tong restbreak. Thus, in the example used above, it. would be likely that 50 menwould work 12 hours per day for the first 15 days and then take thesecond 15 days off, while a second group would rest the first 15 daysand work the second 15-day period. This would be the equivalent of 100man-months (509 men x 1 shift x rotation factor of 2 x 1 month) based ona work week of some 40 hours.
Nevertheless, in the example above, there were no more than 50 menphysically present on the worksite at one time, nor were there more than50 men on the employer’s payroll at one time. Therefore, on the basis ofa definition of a man-month that involves solely the duration of workers’paid presence at the site, there were only 50 man-months of employment.
9●
*
●
●
●o●E-15
especially on a long or remote project. Thus, the total number of
men employed will be larger than the man-months of effort demanded
by the project. For example, a study of field employment during the
1976 summer exploratory drilling program of Canadian Marine Drilling,
Ltd. (Canmar) in the Beaufort Sea revealed that 15 percent of the
employees worked the entire season and 15 percent worked a week or
less. Approximately twice as many people were hired as there were
positions (Collins, 1977).
In this report a distinction is made between on site man-months ofemployment and total man-months. On site man-months represent the
number of men physically present at the worksite qnd on the payroll
(workers on leave rotation are not typically paid) during the project.
This number represents actual labor expenditures for tasks (such as
building an oil terminal, installing a platform, etc.). Total man-
months include on site workers and off site workers. This number
indicates the overall labor force requirements of the project. Monthly
average total labor force levels -- that is, the iqonthly average num-
ber of men engaged in all phases or work during the year -- can be
derived by dividing the total number of man-months x 12 (1)*
VI. The OCS Manpower Model
Estimated manpower requirements for each scenario presented in Chap-
ters 5.0, 6.0, 7.0, and 8.0 are the product of an employment model
originally developed for projecting the manpower requirements of
petroleum development in the Gulf of Alaska(2). The model has been
(1) If on a project that involved one shift per day, a crew of50menworked 12 hours per day for the first half of each month for one year,and a second crew worked for the second half of each month for the year,on site employment would be 600 man-months (50 x 12 months); totalvent would be 1,200 man-months (50 men x 2 x 12 months); and theaverage monthly labor force would be 100 men (1,200 divided by 12).
(2) Northern Gulf of Alaska Petroleum Development Scenarios”, AlaskaOCS Socioeconomic Studies Program Technical Report No. 29 (Dames & Moore,1979a) and “Western Gulf of Alaska Petroleum Development Scenarios”,Alaska OCS Socioeconomic Studies Program Technical Report No. 35 (Dames &Moore, 1979b).
E-16
further refined and adapted for use in Norton Sound (I)* It is assumed
that offshore labor requirements for several tasks in Norton Sound will
be comparable to those projected for Lower Cook Inlet, but not as large
as those foreseen for petroleum development in the Gulf of Alaska, which
are more clearly related to the experience of the North Sea. Labor force
estimates for construction of onshore facilities are assumed to approxi- *
mate or exceed those used in’ the Gulf of Alaska scenarios, except for LNG
plant construction, which”+s assumed to he a. prefabricated, barge-mounted
unit requiring little onsite manpower.
The crew size and length of time required to accomplish a task can vary
enormously from one site, or one situation, to another. Requirements for
building an oil terminal of a certain capacity, fore xample, will depend
to a large extent upon the site available for the facility. The massive
labor requirements of the Valdez terminal built for the trans-Alaska
pipeline were due in large part to the need to excavate and reinforce
a rock mountainside. Offshore construction activity such as pipelining
also depends upon the physical environment (subsea soil conditions, aweather, etc.). The uncertainty of these operations is reflected in the
fact that construction contracts are typically exacuted on a reimbursable
day rate plus fixed fee basis, since contractors dare not quote a per
unit (mile, ton, etc.) basis. The manpower model used in this report is
based upon very general assumptions about labor productivity, the physical
environment, the range and relative scale of operations, and many other
factors.
The scope of employment covered in this model is that which is generated
in the field, that is, direct employment on the platforms, on the supply
boats, barges, and helicopters, at the shore bases, and at field con-
●
●
struction sites if there are any. The clerical,neering, and geological work that occurs off the
shore support bases is not included. Neither is
labor included in this analysis.
administrative, engi-
site or away from the
indirect or induced
*
●o(1) Special assumptions adapting the OCS model for Norton Sound appearin Table E-la.
VII. Description of Model and Assumptions
,,
For maximum analytical utility, manpower estimates are needed for
each month of the year; for onshore as well as offshore employment;
for on site as well as off site employment; and for each major in-
dustrial sector.
Monthly estimates are required because it is necessary to know employment
levels for the months of January and July. Per capita distributions ofstate revenue sharing programs are based on the populations of munici-palities in these months. However, since offshore population cannot
be counted for this purpose, nor can off site population (that is, workers
on leave rotation), it is also necessary to distinguish between these”
categories of employment. Also, for impact analysis generally it is
necessary to distinguish between offshore and onshore labor force levels,
because offshore workers have very little or no contact at all with the
local economy.
To enhance the sophistication of the effort generally and to increase
its usefulness for impact analysis, employment is categorized by the
four main industries that are involved in petroleum development: petro-
leum, construction, transportation, and manufacturing. Probably over
98 percent of the field labor associated with the exploration, develop-
ment, and production of petroleum fall within one of these four Standard
Industrial Classification (SIC) sectors (1).
The first step in model building was to identify the basic tasks of each
phase of petroleum development that generate significant employment. A
unit of analysis, such as a we?l, platform, or construction spread, was
established for each of these labor-generating tasks, which are the basic
“building blocks” of the system. Manpower requirements for each unit of
analysis were estimated, as were the number of shifts worked each day,
and the labor rotation factor for that task. This information is pre-
sented in Tab?e E-1.
(1) Environmental engineering consulting services, and contract com-munications work are sources of minor employment that come to mind thatdo not fall within these four industrial sectors.
E-18
mId
to
Phase
xplorat ion
envelopment
.
I n d u s t r y
A. Petroleum
B. Construction
C. Transportat ion
D. Pianufacturi ng
A. Petroleum
B. Construction
Task
1.
2.
3.
301.
4.
5.
Exploration wel 1
Geophysical andgeologic survey
Shore baseconstruct ion
Artificial island
Helicopter for Rigs
Supply/anchor boatsf o r rigs
6.
7.
8.
9.
10.
11.
12.
13.
14.
15.
Devel opnent dri 11 i ng
Steel jacketinstallation andconsnissioning
Concrete Installationand commissioning
Shore treatmentplant
Shore base
Single legmooring system
Pipeline offshore,gathering, oiland gas
Pipeline offshore,gathering~ oiland gas
Pipeline onshore,trunk, oil and gas
Pipe coating
TABLE E-1
OCS MANPOWER EhiPLOYMENT MODEL
Unit ofAnalysis
Rig
Crew
Base
Spread.
Uel 1
Uel 1
Platform
P1 atform
P1 at form
Plant
Base
System
Spread
Spread
Spread
Pipe coatingoperation
Ouration ofEmployment/
Unit of Analysis’(in months)
Assigned
5
Assigned
Assigned
Same as Task 1
Same as Task 1
Assigned
10
10
6
Assigned
‘ 6
Assigned
Assigned
Assigned
Assigned
—
Crew SizeUnit of Ana!ysisz
~28 0
0 6
25 00 2
Ass~gned
10015
0 5
26 00 I 2
1
28 if 1 rig
1250
2000
0
0
500
1000
1250
0
0
2:
2:
40
Assignedmonthly
1:
2!!
3:
300
175
Ihnnberof
Shifts/Oay
21
;
1
21
1
11
2
21
21
2
01
21
21
21
1
1
Rot at ionFactor
21
I
1.11
;::1
2
1.51
2
21.11
21.11
1.11
01.11
21.11
21.11
21.11
1.11
1.11
ScaleFactor
CrewSize
N/A
!VA
CrewSize
N/A
N/A
N/A
CrewSize
CrewSize
Ass i gned
Crew “Size
Assigned
Assigned
Ass i gned
CrewSize
– “’’l’--,,.. ;.2i
—
TABLE E-I (Cent. )
P-1Ao
Phase
C. Transportation
D. Manufacturing
Task
16.
17.
18.
19.
20.
21.
22.
23.
24.
25.
26.
27.
2B .
29.
30.
Marine terminal
LNG plant
Crude oi 1 pumpstation onshore
Gravel island
Gravel, island
Helicopter supportfor platform
Helicopter supportfor lay barge
Supply/anchor boatsfor platform
Supply/anchor boatsfor lay barge
Tugboats for instal-lation and towout
Tugboats for laybarge spread
Longs horing forplatformconstruct ion
Longshoring forlay barge
Tugboat for SLMS;(Task 11)
Tugboat for SLMS;(Task 11)
Unit ofAnalysis
Terminal
Plant
Station
Spread
Spread “
Platform;same asTasks 7 & 8
Lay bargespread; same asTasks 12 & 13
Platform;same asTasks 7 & 8
Lay bargespread; same asTasks 12 & 13
PI atform
Lay bargespread; same asTasks 12 & 13
Platform;same asTasks 7 & 8
Lay bargespread; same asTasks 12 & 13
Same asTask 11
Same asTask 11
Duration ofEmployment/
Unit of Analysis’(in months)
Assigned
Ass i gned
8
Ass i gned
Ass i gned
Same asTasks 7 & 8
Same asTasks 12 & 13
Same asTasks 7 & 8
Same asTasks 12 & 13
Same asTasks 7 & 8
Same asTasks 12 & 13
Same asTasks 7 & 8
Same asTasks 12 & 13
Same asTask 11
Same asTask 11
(number iOffshore
o
0
0
100
0
0
390
650
40
20
0
0
10
13
Crew SizeUnit of Analysis’
people)Onshore
Assignedmonthly
Ass i gnedmonthly
100
15
5
5
012
1!
o
0
20
20
0
0
NumberofShifts/Oay
1
1
1
2
1
1
1
11
11
1
1
1
1
1
1
lotationFactor
1.11
1.11
1.11
1.5
1.11
2
2
1.51
1.51
1.5
1.5
1
1
1.5
1.5
ScaleFactor
Assigned
Assigned
CrewSize
CrewSize
CrewSize
N/A
N/A
N/A
N/A
N/A
N/A
CrewSize
CrewSize
N/A
N/A
TA~LE E-1 (Cont. )
Phase
roduct ion
Industry
A. Petroleum
B. Construction
C . T r a n s p o r t a t i o n
D. Manufacturing
Task
31.
32.
33.
34.
35.
36.
37,
38,
Operations andmaintenance (rout~neprevent ive)
Oil well workoverand stimulation
Maintenance and Re-pair for platformand supply boats(replacement ofp a r t s , r e b u i l d ,paint ing, etc. )
,Helicopters. forpl atfotm
Supply boats forplatform
Terminal and pipe-line operations
Longshoring forplatforms
LNG operations
Unit ofAnalysis
P1 at form
P1 atfonn
Platform
Platform
PI at form
Terminal
PI atforms
LNG plant
Duration ofEmployment/
Unit of Analysis’(in months)
Assigned
Ass i gned
Assigned
Same as Task 31
Same as Task 31
Assigned
Same as Task 31
Assigned
Crew SizeUnit of I
(number wOffshore
360
15
80
0
12
0
0
0
~lysis=Eople)Onshore
o4
0
08
5
0
Assigned
4
Assigned
Number
s:ifts/Oay
21
1
11
1
1
2
1
2
ot at ionFactor
21
2
21
2
1.5
2
1
2
S c a l eFactor
CrewSize
t4/A
CrewSize
N/A
N/A
N/A
CrewSize
N/A.—
~ Different labor force values may be substituted for these if deemed appropriate by site-specific characteristics.~ This is the crew size or estimated average monthly shift labor force over the duration of the project. “Assigned” means that scenario-specific valuesare used, and that no constant values are appropriate,Additional notes on next page.
Source: Dames & Moore
●o* ● ●
NOTES TO TABLE E-1
I Task I II Average 28-man crew per shift on dri 1 ling vessel and six shore-based positions (clerks, expediters,
administ rators) ; shi f t on dr i lling vessel inc ludes cater ing and oi 1 f ie ld serv ice personnel . N u m -ber of rigs per year is determined by the number of wel is/year x months required to dril 1 each wel 1divided by the number of months in the dri llina season.
2 Approximately one month of geophysical work per wel 1 based on 200 miles of seismic 1 ines per wel 1at approximately 15 miles/day x 2 (weather factor); 25-man crew and two onshore !JOsitions, crewcan work from May through September.
3 !lequlrements for temporary shore base construction varies with lease area.
I 4I
One helicopter per drl 1 Ii ng vessel ; two pilots and three mechanics per helicopter; consideredons here ernp loyment.
5 Two supply anchor boats per rig; each with 13-man crew.
6 One or two dri 1 ling rigs per platform; average 28-man dri 11 i ng crew and six shore-based positionsper rig; shift on drilling vesses includes catering and oil field service personnel.
7, 8, 9 Includes al 1 aspects of towout, placement, pile driving, module installation, and hookup of deckequipment; a lso includes crew support (cater ing personnel ) .
10 See Table 5-7.
11 This task includes all subsea tie-ins of underwater completions.
12 Rate of progress assumed to be average af one mile per day for all gathering lines; scale factorsnot applied to gathering l i n e .
13 Rate of progress averages .75 mile per day of medium-sized teunk line in water of medium depth;scale factors applied in shallow or deeper water and for pipe diameter; rate of progress makesallowance for weather down time, tie-ins, and mobilization and demobilization.
14 Rate of progress averages .3 mfle per day of buried medium-sized onshore trunk line in moderateterrain; scale factors applied for elevated pipe or rocky terrain and for pipe diameter.
15 Rate of progress for pipe coating is one mile/day for 20- to 36-inch pipe; 1.5 mile for 10- to19-inch pipe.
16 See Table 5-7.
17 See Table 5-7,
20 See Table 5-7.
21 One helicopter per platform.
22 One helicopter per lay barge spread.
23 Three supply/anchor boats per platform.
24 Five supply/anchor boats per lay barge spread.
25 Four tugs for towout per platform; 10-man crew per boat.
26 Two tugs per lay barge spread; 10-man crew,
30 One helicopter per platform.
31 Assumed to begin fn first year of platfoim production (also tasks 33, 34, 35, and 37).
32 Assumed to begin five years after well production.
33 This maintenance activity is assumed to begin two years after start-up of production.
35 One supply boat per platform.
E-22
‘ask
$
3
301
6
7
13
L14
15
9
TABLE E-1a(Attachment Of Table E-l)
SPECIAL MANPOWER ASSUMPTIONS FOR NORTON SOUND
I
special Assumptions —.
Length of drilling seasons is dght months on the average; ice breakers will allow rigs &o operatefrom April 1 to November 31. Gravel islands will permit year round drilling. Drilling startdate on gravel islands is either two months or four months from the start of island construction
(see task 301 13elow).
E?cploratory drilling will be supplied from Nome.
One equipment spread can build an island in 7.5-m (2!j-foot) water depth in two months, or anksland in 15-meter (50-foot) water
Assumes 4!5 days per well, or eight
Scale factor of .7.
Ml offshore pipelining is enteredof .4 mile per day (partial mouthsare based on large, modern, highly
depth in four months.
wells per year for both oil and gas production wells.
under this task with scale factor of .7 and a rate of progressaxe rcmntieti up) . Proauccivity shown in the notes to Table E-1efficient equipment currently used in the North Sea and Gulf
of Mexico. This equipment (e.g. reel lay barges) is very expensive, and because total offshorepipelining requirements in Norton Sound are not large, and because the work season is short, itis assumed that smaller, less efficient lay barges will be used. These will require less manpower<ban the larger equipment spreads.
Scale factor of 1.3 because of arctic conditions.
Rate of progress assumed to be .75 mile per day (approximately 100 lengths of 40-foot pipe perday or 8.25 per hour). Scale factor is .7. This reduced productivity and manpower is based onunderlying assumption in task 13 above.
9 *
Crew size or the length of employment for some activities is not influ-
enced by the size of the oil field or physical conditions such as water
depth. Transportation crew sizes, for example, are the same for offshore
platforms in shallow and deep water for large and small fields. This is
not the case with other activities such as platform installation or
pipelaying. Here, the size of the field (which determines the size and
number of platforms used) and the depth of water are critical determi-
nants of crew size and duratfon of employment. To l~ccount for these
variations, a general set of scale factors was used to increase or
decrease labor requirements when field size and other conditions re-
quired that adjustments be made. Scale factors are shown in Table E-2.
Scale factors are applied to the crew size.
Scale factors are a necessary element of the manpower model to reduce
to a manageable number of inputs required by it, and also to generate
estimates for which specific references are not available in the litera-
ture. Scale factors in Table E-2 were derived by a process of trial and
error from a wide variety of information about crew sizes and manpower
requirements of petroleum activities of a different nature and scale.
They represent a single set of factors that seem to best express the
relationships that exist between manpower demands oj disparate projectsand activities. For example, in the case of platform operating personnel
(task 31, Table E-1), the small offshore platform ot Marathon Oil Companyin Upper Cook Inlet (Dolly Varden) has an offshore crew of approximately
23 per shift (46 total, Marathon Oil Company, 1978): while the very large
North Sea platforms have crews of approximately 60 per shift (120 total,
Addison,1978). Thus, these two crew sizes have a relationship that
generally matches the scale factors in Table E-2. They also suggest a
crew size for a platform of moderate and large size. The scale factor of
1.0 corresponds to a crew of 35 (derived), a scale factor of .7 corresponds
to a crew of 25 (contrasted to 23 of Marathon platforml, and a scale
factor of 1.7 corresponds to a crew size of 61(1). While the use of a
(1) An actual platform operating crew will depend upon the volume ofgas and liquids produced, the extent of secondary recovery (water floodpumps, gas life compressors, etc.); and the extent of primary processing.Even a large near shore platform without secondary recovery could operate
) with a relatively small operating workforce. Also, ~ producing platformwill have a larger day crew than a night crew (i.e. shifts are not thesame size). However, total platform population is divided into two crewsof equal size to simplify the modeling of this employment.
E-24
TABLE E-2
SCALE FACTORS USED TO ACCOUNT FOR INFLUENCE OFFIELD SIZE AND OTHER CONDITIONS ON MANPOWER REQUIREMENTS
(Base Case)
-Factor
0.7
1.0
1.3
1.7
Field Size
Smal 1
Moderate
Large
Very Large
—
Water Depth_
Shal 1 ow
Moderate
Deep
Very Deep
Pipelay ConditionsOffshore and Onshore
Easy
Moderate
Difficult
Very Difficult
o
Source: Dames & Moore
E-25
single general set of scale factors introduces a measure of distortion
into the manpower estimating process, the distortion seems to be within
an acceptable overall range of accuracy.
Occasional deviation from the scale factors in Tables E-2 is necessary,
as for example in the construction and operation of major onshore facili-
ties which do not appear to have a simple, linear relationship between
project size and labor force requirements. Also, in the case of these
onshore facilities, monthly construction labor force levels vary greatly,
so it was necessary to develop complete sets of monthly employment
figures. These estimates are shown in Tables E-3a and E-3b. The numbers
in Tables E-3a and E-3b are general estimates derived from available infor-
information about the length of construction, peak” workforce, and operating
‘1). It was assumed that peak employmentcrew size in similar facilities
on a construction project of this type would reach a brief plateau of
approximately midway through the project, and that it would steadily
increase prior to the peak and steadily decrease after the peak had been
reached. Thus, a graph of the manpower requirements for these projects
would generally approximate an equilateral triangle with a blunt tip.
This assumption allowed monthly manpower estimates tQ be calculated once
the peak level and construction period were identified.
Identifying typical crew size and reasonable monthl~ average workforqe
levels for the various labor-generating activities constituted the major
research task. Information was obtained from many sources -- trade
journals (advertisements as well as articles), industry equipment specifi-
cations, interviews with contractors experienced in offshore work,
government studies including offshore petroleum impact assessment,
professional papers, and cost estimating manuals.
(1) Among the more helpful references are: Sullom Voe EnvironmentalAdvisory Group (1976); El Paso Alaska Co. (1974); Dames & Moore (1974);Crofts (1978); Akin (1978); Pipeline and Gas Journal (1978a); Larminie(1978); Addison (1978) ; Duggan (1978); Trainer et al. (1976); &laskaConstruction (1966); Alaska Construction (1967b); Bradner (196~hesesources provided information about peak workforce levels and/or construc-
) tion periods for oil terminals or LNG plants. Shore base constructionestimates in Tables 5-6a and 5-6b are by Dames & Moore.
E-26
F a c i l i t y
Oil T e r m i n a l
(i3D)
LNG Plant(MMCFD)
Shore Base(field produc-tion in MMBD)
TABLE E-3a
MANPOWER ESTIMATES FOR MAJOR ONSHORE FACILITIES, SUMMARY1
Size
Small
Medium
Large
Very Large
Smal 1
Medium
Large
Very Large
Med i urn
Large
Approximate Capacity
200,000 minus
200,000 - 500,000
500,000 - 1,000,000
1,000,000 plus
500 minus
500- 1,000
1,000 - 1,500
1,500 plus— .1.5 minus
1.5 minus
‘ Monthly manpower requirements presented in Table E-3b.2 Two shifts and a rotation factor of two are assumed.
Source: Dames &i Moore
a ●
Duration ofConstruction
18
24
36
36
24
24
36
36
12
16
*
ApproximatePeak Construction
Employment(number of people)
350
750
1,200
3,500
400
800
2,000
4,000
400
700
OperatingPersonnel(Crew Size)z
16
42
55
70
20
30
50
125
-.
-.
● 9 *o
●
TA8LE E-3b
MONTHLY MANPOUER LOAD [ NG ESTlf4ATES , MAJOR ONSHORE CONSTRUCTION PROJECTS
F a c i l i t y : Oil TerminalS i z e : S m a l lD u r a t i o n ’ o f C o n s t r u c t i o n : 1 8 m o n t h sApproximate Peak Employment (number of people): 350
Month: 2 3 4 8 10 11 12 13 14 15 16 17 18Workers: ;9 78 117 156 1;5 2!4 2~3 312 3;1 351 312 273 234 195 156 117 ?8 39
Facility: Oil TerminalS i z e : ‘Md i urnOuration of Construction: 24 monthsApproximate Peak Employment (number of people): 750
Month: 1 2 7 8 9 10 ‘ 12 131;6 2:8 3?0 3;2
16 17Workers: 62
19 20 21 22 23 24124 434 496 558 620 ::2 744 744 ;:2 :;0 558 496 i:4 372 310 248 186 124 62
Facility: Oil TerminalSize: LargeDuration of Construction: 36 monthsApproximate Peak Employment (number of people): 1200
mI Month: 1 4 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 23 24E Workers: 67 1:4 2:1 268 3:5 402 469 536 603 670 73? 804 871 938 1005 1072 1139 1206 1206 1 1 3 9 1;;2 1%5 938 871
Month: 26 27 28 29 30 31 32 33 34 35 36Workers: ::4 737 670 603 536 469 402 335 268 201 134 67
Facility: Oil TerminalSize: Very LargeOuration of Construction: 36 monthsApproximate Peak Employment (number of people): 3500
Month: 1 2 3 4 12 13 14 15 16 17Workers: 194 388 582 776 9;0 11:4 1318 15:2 17;6 l~?O 21$4
18 . 19 20 21 22 23 242329 2522 2716 2910 3104 3298 3500 3298 3298 3104 2910 2716 2522
Month: 25 26 27 28 30 31 32 33 34 35 36Workers: 2328 2134 1940 1746 l;g2 1358 1164 970 776 582 388 1!34
Facility: Barge-Mounted LNG PlantSize: SmallDuration of Construction: 12 monthsApproximate Peak Employment (number of people): 150
Month: 2 3 .8;5 50 75
10 11 12Workers: 1:0 1:5 1:0 1:0 125 1;0 75 50 25
o
. .
mi--
. .
I
. .Ill
o0-$
. .
N-10. .
E-29
A c o m p u t e r w a s u t i l i z e d t o c a l c u l a t e a n d s u m t h e m a n p o w e r r e q u i r e m e n t s
for each scenario. It used the following basic formula for each task,
all of which were coded by industry:
Number of units x
of shifts x rotat
The information in Tab”
model. For each task,
crew size x duration of task x number
on factor x scale factor
e E-1 comprises the framework of the computer
inputs were provided for the number of units, the
starting year and month, and if necessary the duration of employment for
the unit. Because most tasks involved units which started and ended at
different times, a separate entry was usually required for each unit.
For example, platforms are built and go into production at different
times, so each platform was entered separately with approximate dates,
lengths of operation, scale factors, etc.
Off site employment is derived from the rotation factor. If the rota-
tion factor is two, then one-half of the total manpower requirement for
the task would be off sitk each month; if 1.5, one-third would be off
site each month; and if 1.11, slightlymore than ore-tenthsite each month.
Transportation requirements are triggered by petroleum and
would be off
construction
activity. Thus, the input for number of units, starting dates, and dura-
ation of work for the transportation tasks were tied to the same inputs
for each petroleum and construction task. For example, each pipelaying
spread requires tug and supply boat service for the same length of time
the spread is working. Thus, for each pipelaying spread entered (tasks
12 and 13), its transportation requirements were automatically calculated
and assigned to the same months.
A hand calculated example that illustrates in
made by the model is presented in a companiondetail the computations
report(l).
(1) Alaska OCS Socioeconomic Studies Program, Northern Gulf of AlaskaPetroleum Development Scenarios, Appendix D, Dames & Moore, 19/9a).
E-30
Summary employment tables in Chapter 2.0 show total man-months of labor for
each year. Employment for each month has been calculated separately and is
available if needed.
VIII, Alternative Scenario Manpower Estimates and Scenario Specifications
After completion of a draft of this report, certain modifications were made
to the OCS manpower model and scenario oil and gas Production specificat”
that warranted a second run of the computer model.
The modifications to the manpower model are containl:d in Tables E-4 (Rev
Tab?e E-l), E-4a (Revised Table E-1a), and E-5 (Rev”sed Tableprincipal modifications include:
s Introduction of seasonality assumptions int{~ platform
and resupply activities (Tasks 31, 33, and 25);
8-17). The
maintenance
ons
sed
a Reduction in the numbers of helicopters servicing platforms and
related employment (Task 30);
o Reduction of onshore freight handling emplo~’ment for platforms (Task
37).
These revisions mainly affect onshore service base employment which
reduced as a result.
The second set of factors that have altered the scerario employment
are changes in the scenario oil and gas production specifications.
explanation is required.
The scenario oil and gas production flows
7-13, 8-12, and 8-13 do not reflect rigid
O*
is
estimates
Some
e
shown in Tables 6-12, 6-13, 7-12,
application of the results of the
economic analysis to production flows. The production profiles have not
been cut off when the field economic limits have been reached, i.e., when
incremental per barrel costs first exceed incremental perbarrel revenue.
The calculated field shutdown points are as follows:
E-31 ●
11.5 BCF/year - Single gas platform system
23.0 BCF/year - Two gas platform system
2.2 MMBBL/year - Single oil platform system
4.4 MMBBL/year - Two oil platform system
6.3 MMBBL/year - Three oil platform system
Applying these cutoffs to the field producing profiles (the tota? resources
of the fields equals the U.S.G.S. resource estimate) would have “produced”
approximately 3 to 4 percent less oil and gas than the USGS estimates.
Conversely, to “produce” the total USGS resource estimates would have re-
quired total field reserves somewhat larger than the USGS estimate.
Applying the economic results to the scenario production statistics causes
field production to be terminated somewhat earlier and the aggregate pro-
duction to be reduced in later years as shown in Tables E-6, E-7, E-8, E-9,E-10, and E-n, which are revisions of Tables 6-12, 6-13, 7-12, 7-13, 8-12,
and 8-13. I n t u r n , t h e o p e r a t i o n a l l i f e o f t h e p l a t f o r m s a n d m a j o r s h o r e
facilities is reduced as shown in Tables E-12, E-131 E-14, E-15, E-16, and
E-17, which are revisions of scenario Tables 6-11, 6-17, 7-11, 7-14, 8-11,
and 8-14, respectively.
These scenario specification changes, along with the OCS manpower model
modifications, were entered in the computer to produce an alternative set of
manpower estimates for the scenarios. The overall reduction in manpower
requirements reflects the sensitivity of the model to changes in assumptions
about the ability to conduct resupply operations year-round by sea. The
reduction also reflects the significant changes that can result in what would
appear to be a relatively minor reduction (3 to 4 percent) in the oil and gas
produced. The main reason for this significant impact is that reduction or
cutoff of production occurs at the tail
impact is greatest,
The alternate manpower estimates based
end of the field lives where the
on these modifications for the
scenarios described in Chapters 5.0, 6.0, 7.0, and 8.0 are presented in
Tables E-18 through E-33.1
E-32
!j ~Uu . In. m. . . .V ‘---’_ --N--
i!
-.1
u-l
.N~O 000 0 OeoornoaUlo
0$. N
22 .
.-.x,
TAILS E-n [Cont. )
Phase Industry
.“
C. l’rans~rtation
D. Manufacturing
Task
16.
17.
18.
19.
20.
21.
2 2 .
23.
24.
25.
26.
27.
28.
29.
30.
Uarine terminal
LNG plant
Crude oil pwpstation onshore
Gravel island
Gravel island
Hal icopter supportfor platfona
Helicopter supportfor lay barge
Sopply/ancber boatsfor platform
Supply/anchor boatsfor lay barge
Togboats for mstaL-la tio n and towout
Tugboats for laybarge spread
Umgshoring forplatfotmconstruction
U3ngshering forlay barge
Tugboat for SIJJW(Task 11)
supply for SLt4SJ(Task 11)
mit ofAnalysis
Terminal
P1 ant
station
Spread
Spread
Platform;same asTasks 7 & 8
by bargespread; same aTasks 12 & 13
P1 atf orm Jsame asTasks 7 E+ 6
LSy bargespread # same aTasks 12 S 13
Platform
LSy bargespread; same aTasks 12 & 13
Platform;dame asTa8ks 7 & 8
Uy bargespread z same aTasks 12 6 13
Same asTask 11
Ssme asTask 11
Duration ofEmployment/
lm.it of Analysisl(in months)
Msigned
Assigned
8
Assigned
Assigned
Ssme asTasks 7 & 8
Same asTasks 12 & 13
Same asTasks 7 L 8
t+tme asTasks 12 & 13
same asTasks 7 & 8
Same asTasks 12 & 13
Same asTasks 7 6 8
Same asTasks 12 S 13
Same asTask 11
Same asTask 11
Crew Ed ze[fait OF Asalysie2(number of
Offshore
o
0
0
100
0
0
390
6So
40
20
0
0
10
13
,ople)Onshore
Assi~edrmnthly
AssignedmontNy
100
15
5
5
012
012
0
0
20
20
0
0
N u m b e r
ofshifts/Day
t
1
1
2
1
1
1
11
11
1
1
1
1
1
1
titat ionFactor
1.11
1 . 1 1
1 . 1 1
1.5
1.11
2
2
1.51
1.s1
1.5
1.5
1
1
1.5
1.5
ScaleFactor
Aesigne
Aasigne
(X ewsize
CrewSize
CrewSize
N/A
N/A
N/&
N/A
N/A
N/A
CrewSize
CrewS i z e
t4/A
N/h
TA8LS E-2 (Cont. )
m(3ul
Phase
Hlduct ion
Industry
A. Petrolerns
B . C o n s t r u c t i o n .
c. ‘1’ransprtatiom
D. &a nuf actur~nq
Task
31.
32.
33.
34.
35.
36.
37.
38.
Operations andmaintenance ( roukinpreventive)
Oil well workoverand stimulation
Maintenance and E@-pair for platformand SUPfi y boa ts(replacement ofJjsrts, rebuild,pinting, etc. )
Mel icopters forplatform
supply bests forplatform
Terminal and pipe-line operdt.io~sFreight handlingplatforms
LNG operations
Dnit ofAnalysis
P l a t f o r m
Platform
Platform
mm Eform
Platform
Terminal
Platforms
LNG plant
!Xmation ofEmployment/
Unit of Analysis ](in months)
Assigned
Assigrred
Assigned
- Same as Taak 31
Assigned
Assigned
Same as Task 31
Assigned
Crew Sizeunit of Analysis 2(number o
7 @ T & z u -
360
15
80
0
12-seas0r4al6 month
o
0
0
Pe;ple )Onshore
o2
0
04
+ seasmsl12 months -6-9 months
3
0
Assigned
3
Assigned
Numberof
shifts/Oay
21
1
$!
1
1
2
1
2
ROtatiorFactor
21
2
21
2
a.5
2
1
2
1Dif f.=mnt ldbOr fOrCe values may be substituted for these if deemed appropriate by site-specific characteristics.
2This is the crew size or estimated average monthly shift labor force over the duration of the project.ate used, “Assigned” means that scenario-specific valuesand that no constant values are appropriate.
Additional notes on next page,
Source: D a m e s & MOOre
●e
● e
ScaleFactor
CrewSize
ti/A
CrewSize
N/A
N/A
N/h
CrewSize
N/A
NOTES TO Ttd3LE E-4
wL!-.-...Average 28-man crew per shift on drilling vessel and six shore-based positions (clerks, expediters,
a d m i n i s t r a t o r s ) ; s h i f t o n dril ling vessel inc ludes cater ing and oi l f ie ld serv ice personnel . N u m -ber of rigs per year Is determined by the number of wel Is/year x months required to dri 11 each wel 1divided by the number of months in the dri 11 i ng season.
2 Approximately one month of geophysical work per wel 1 based on 200 miles of seismic 1 ines per wel 1at approximately 15 mi les/day x 2 (weather factor) ; Z5-man crew and two onshore posi t ions, crewcan work from May through September.
3 Requirements for temporary shore base construction varies with 1 ease area.
4 One hel fcopter per dri 11 ing vessel ; two pi lots and three mechanics per helicopter; consideredonshore employment.
51TWO supply anchor boats per r ig; each wi th 13-man crew.
6 One or two drilling rigs per platform; average 28-man dri 1 ling crew and six shore-based positionsper r ig ; sh i f t on dr i l l ing vesses i n c l u d e s c a t e r i n g a n d o i l f i e l d s e r v i c e p e r s o n n e l .
7, 8, 9 Includes al 1 aspects of towout, placement, pile driving, module installation, and hookup of deckequipment; also includes crew support (catering personnel ).
10 See Table 5-7.I
11 This task includes al 1 subsea tie-ins of underwater completions.
12 Rate of progress assumed to be average of one mile per day for al 1 gathering 1 ines; seal e factorsnot appl ied to gather ing l ine .
13 Rate of progress averages .75 mile per day of medium-sized trunk 1 ine in water of medium depth;scale factors appl ied in shal low or deeper water and for pipe diameter; rate of progress makesallowance for weather down time, tie-ins, and mobil ization and demobilization.
14 Rate of progress averages .3 mile per day of buried medium-sized onshore trunk 1 ine in moderateterrain; scale factors appl ied for elevated pipe or rocky terrain and for pipe diameter.
15 Rate of progress for pipe coating is one mile/day for 20- to 36-inch pipe; 1.5 mile for 10- to19-inch pipe.
16 See Table 5-7.
17 See Table 5-7.
20 See Table 5-7. 1I 21 One helicopter per platform. I
22 One helicopter per lay barge spread.
23 Three supply/anchor boats per platform.
24 Five supply/anchor boats per 1 ay barge spread.1
25 Four tugs for towout per platform; 10-man crew per boat. I
26 Two tugs per 1 ay barge spread; 10-man crew.
30 .5 helicopter per pl atfonn (3 man crewfplatform). J
31 Assumed to begin in first year of platform production (also tasks 33, 34, 35, and 37).
I 32 Assumed to begin five years after wel 1 product ion.
‘ l=l===:~:patfo.
This maintenance activity is assumed to begin two years after start-up of p~oduction.
I 1
. .E-36
TABLE E-.4a(Attachment of Table E-,4)
y’1
(A)--l
Paslt
f
3
3 0 1
i
7
13
14
15
3 3
35
●
SPECIAL MANPOWER ASSUMPTIONS FOR NORTON SOUND
Special Assumptions ‘
Length of drilling seasons is eight months on We average; ice breakers will a3.low rigs ko operatefrca April 3 to November 31. Gravel islands will permit year round drilling. Drilling startdate on gravel islands is either two months or four months from the start of island construction(see task 301 below).
Exploratory drilling will be supplied from I?ome.
@e equipment spread can build an island in 7.5-m (25-foot) water depth in two months, or anisland in 15-meter (50-foot] water depth in four m o n t h s .
Assumes 45 days per well, or eight wells per year for both oil and gas production wells.
Scale factor of .7.
AI1 offshore pipelining is entered under this task with scale factor of .7 and a rate of progressof .4 mile per day (~artial months are rounded up) . Productivity shown in the notes to Table E-1are based on large, modecn, highly efficient equipment currently used in the North Sea and Gulfof Mexico. This equipment (e.g. reel lay barges) is very expensive, and because total offshorepipelining requirements in Norton Sound are not large, and because the work season is short, itis assumed that smaller, less efficient lay barges will be used. These will require less manpowerthan the larger equipment spreads.
Scale factor of 1.3 because of arctic conditions.
Rate of progress assumed to be .75 mile per day (approximately 100 lengths of 40-foot pipe perday or 8.25 per hour). Scale factor is .7. This reduced productivity and manpower is based onunderlying assumption in task 13 above.
This activity is assumed to occur seasonally; from June through September.
Supply boats are assumed to operate only from May through October; helicopter supply platformsduring ice season.
o● ● ● * *
9 ●
TABLE E-5..—. —LIST OF TASKS BY ACTIVXN
,- Servfce 83,,,
2
~wco
3
4
5
6
1
8
9
10
Task 1 -Task 2 -T a s k 5 -Task ~ -Task -Task 8 -Task 11 -T a s k 1 2 -T a s k 1 3 -
Task 2 0 -T a s k 2 3 -T a s k 2 4 -T a s k 2 7 -T a s k 2 8 -Task 31 -T a s k 3 3 -T a s k 3 ? -Task 301 -
ONSHORE
( O n s h o r e Eumlovment - which would inc lude all.– .-o n s h o r e a d m i n i s t r a t i o n , s e r v i c e b a s e o p e r a t i o n s ,r ig and p l a t f o r m s e r v i c eExploratlonldell D r i l l i n g 12Geophysical Explorat ionSupply/Anchor Boats for RigsDevelopment Dr i l l ing 13Steel Jacket Insta l lat ion and CommissioningConcrete Insta l la t ions and ConvisissioningSingle-Leg Mooring SystemP i p e l i n e - O f f s h o r e , G a t h e r i n g , Oil and GasP i p e l i n e - O f f s h o r e , T r u n k , OiI and GasGravel Island Construction 14Supply/Anchor Boats for Plat formSupply /Anchor Boats forl.ay BargeLongshoring f o r PlatfomnLongshorfng for Lay B a r g ePlatform Operat ionMaintenance and Repairs for Plat formLongshoring f o r P l a t f o r m [ P r o d u c t i o n ) 15Gravel Island C o n s t r u c t i o n
Helicopter Service- H e l i c o p t e r f o r R i g s
T:;k 2t - Hel icopter Support for Plat formTask 22 - Hel icopter Support f o r L a y B a r g eT a s k 3 4 - H e l i c o p t e r f o r P l a t f o r m
Construct ionS e r v i c e IJase
T 3 - Shore Base ConstructionT:tk 1 0 - Shore Base Construction
Pipe Coat ingTask 15 - Pipe Coat ing
Onshore Pipel inesTask 4 - P ipe l ine , Onshore , Trunk, Oi l and Gas
Terminal~ 1 6 - M a r i n e T e r m i n a l ( a s s u m e d t o b e o i l t e r m i n a l )
Task 18 - Crude Oil Pwnp S t a t i o n O n s h o r e
LNG PlantTask 17 - UiG Plant
form Construct ionP l a t f o r m S i t e P r e p a r a t i o n
: C%% P l a t f o r m C o n s t r u c t i o n
Oi l Terminal Operat ionsT a s k 3 6 .- Terndnaf and Pipel ine Operat ions
LNG Plant Operat ionsTask 13- Lffi llperat ions
16
OFFSHORE
%IC 2- Geophysical and@ological Survey
~Task 1 - Exploratlonblell
P l a t f o r m s~~6-Oevel ornnent D r i l l i n g
Task 31 - Operat ionsT a s k 3 2 - Uorkover andliell S t i m u l a t i o nT a s k 3 3 - M a i n t e n a n c e a n d R e p a i r s f o r P l a t f o r m s
P l a t f o r m I n s t a l l a t i o n .Jacket Insta l lat ion and Commissioning
T%k 8: C%!rete I n s t a l l a t i o n a n d C o m m i s s i o n i n gT~sk 11 - Single-l.eg i400ring S y s t e mT a s k 2 0 - G r a v e l I s l a n d C o n s t r u c t i o nT a s k 3 0 1 - Gravel Island C o n s t r u c t i o n
O f f s h o r e P i p e l i n e C o n s t r u c t i o nffshore, Gather ing, Oi l and Gas
PiEl;% Offshore, Trunk, Oil and Gas
~ply/AnchorfTug Boat/_knchor 8oats f o r R i g s
Tj~k 23: S;~~l~/Anchor Boats f o r P l a t f o r mT a s k 24- Supply /Anchor Boats for Lay BargeTask 25 - Tugboats for Insta l la t ion and TowoutTask 26 - Tugboats for Lay Barge SpreadT a s k 2 9 - Tugboats for SLMST a s k 3 0 - SUDDIY Boat f o r SLMST a s k 3 5 - Supp)jI aoat for SMS
TA8LE E.% (6-12)*
CalendarYeitr
1983198419851986198719881989199019911992199319941995199519971998199920002001200220032004200520062007200820092010201120122013201420152016
HIGH FINO SCENARIO PRODUCTION BY YEAR FOR lNDIVIDUA. FIELDS AND TOTAL - OIL
PRODuCTIO N INYew A f t e r moundLease S a l e U(J
123456789
10111213141516171819202122232425262728293031323334
509
7.00824.52845.5525 6 . 0 6 4
5 6 . 0 6 4
5 4 . 0 0 5
4 6 . 3 5 4
M.598
3 2 . 1 6 8
2 6 . 8 4 0
2 2 . 4 2 0
18.757
15.221
12.703
1 0 . 6 1 6
8 . 8 8 6
7 . 4 5 2
6 . 2 6 3
5 . 3 2 8
4 . 4 1 7
Peak 0 1 1 Pt%ductton * 7 6 4 , 4 0 0 bfd.
Source: Dames & Hoore
7.00814.01621.02428.03227.05022.40117.43213.89711.0008.8866.8355.2504.1543.2862.600
.
zoo
7 . 0 0 8
14.016
2 1 . 0 2 4
2 8 . 0 3 2
2 7 . 0 5 0
2 2 . 4 0 1
17.432
1 3 . 8 9 7
1 1 . 0 0 0
8 * 8 8 6
6 . 8 3 5
5 . 2 6 0
4 . 1 5 4
3 . 2 8 6 ,
2 . 6 0 0
16BL YEAR B ~Centr]~“— .
7.008
24.528
45.552
56.064
56.064
5 4 . 0 0 5
4 6 . 3 5 4
3 8 . 5 9 8
3 2 . 1 6 8
2 6 . 8 4 0
2 2 . 4 2 0
18.757
15.221
12.703
10.616
8 . 8 8 6
?.452
6 . 2 6 3
5 . 3 2 8
4.417
● Number in Parentheses is that of the original table which has been revised
E-39
[ELD SIZE)ound
200
7.00814.01621.02428.03227.05022.40117.43213.89711.0008.8866.8355.2504.1543.2862.600
f8BL)Outer
750
7 . 0 0 8
2 4 . 5 2 8
5 2 . 5 6 0
73.584
8 4 . 0 9 6
8 4 . 0 9 6
7 6 . 7 0 8
6 2 . 4 5 3
51.”293
4 0 . 8 6 9
3 3 . 8 8 5
2 8 . 0 9 4
2 3 . 2 9 3
19.312
16.012
1 3 . 2 7 4
11.007
9 . 1 2 6
7 . 5 6 6
7 . 0 8 8
~250
7.00817.52028.03228.03228.03227.982.24.90620.64717.11614.18711.7639.7518.0846.701
.
.
7 . 0 0 8
38.544
98.088
178.704
245.280
277.279
278.995
262.799
230.211
192.860
157.757
128.936
105.531
86.493
70.655
57.891
39.888
32.910
25.192
20.846
12.416
4.417
TABLE E-7 (6- 13)*
HIGH FIND SCENARIO PRODUCTION By YEAR FOR INDIVIDUAL FIELDS AND TOTAL - NON-ASSOCIATEO GAS
L
, ,.”w””, .”., . . . w“, .-, ,0. “. . ---- “.-.. ,---
Calendar Year After Central SoundYear Lease Sale 1000 1200 Totals
1983 11984 21985 31986 41987 51988 61989 7 21.D24 21.024
1990 8 42.048 21.024 63.0721991 9 63.072 42.048 105.1201992 10 84.096 63.072 21.024 168.192
1993 11 84.096 84.096 42.048 . 210..2401994 12 84.096 84.096 63.0721995 13
231.26484.096 84.096 84.096 252.288
1996 14 84.096 84.096 84.096 252.2881997 15 84.096 84.096 84.096 , 252.2881998 16 84.096 84.096 84.096 252.2881999 17 ‘ 72.423 84.096 84.096 240.6152000 18 54.122 72.423 @l.096 210.6412001 19 40.521 54.122 84.096 178.7392002 20 30.310 40.521 84.096 154.9272003 21 22.672 30.310 44.096 137.0782004 22 16.958 22.672 69.600 109.232005 23 12.685 16.958 54.680 84.3232006 24 9.788 12.685 42.933 65.1062007 25 7.097 33.710 50.2952008 26 5.309 2 6 . 4 6 8 38.8742009 27 20.782 26.0912010 28 16.317 16.3172011 2 9 12.812 12.8122012 302013 312014 322015 33‘2016 342017 35
) Peak Gas Production = 691.200 mancfd.
Source: Dames & Moore
* Number in Parentheses is that of the original table which has been revised
“.
E-40
TABLE E-8 (7-12)*
MEDIUM FIND SCENAR 10 PRODUCTION BY YEAR FOR lND IV I DUAL FIELDS AND TDTAL - OIL
PR~TION Ih MMBBL Y EAR BY F IELD SIZE (MMBBL)Calendar Year After Inner Sound Cent ra l Sound
YearOuter Sound
Lease Sale 200 200 250 250 Totals
1983 11984 21985 31986 4
1987 51988 61989 7 7.008 7.0081990 8 24.528 7.008 7.008 31.5361991 9 7*008 45.552 17.520 7.008 77.088
1992 10 14;016 7.008 56.064 28.032 17.520 122.640
1993 11 21.024 14.016 56.064 28.032 28.032 147.1681994 12 28.024 21.024 54.005 28.032 20.032 159.1251995 13 27.050 28.032 46.354 27.982 28.032 157.4501996 14 22.401 27.050 38.598 24.906 27.982 140.9371997 15 17.432 22.401 32.168 20.647 24.906 117.5541998 16 13.897 17.432 26.840 17.116 20.647 95.9321999 17 11.000 13.897 21.420 14.187 17.116 77.6202000 18 ~ 8.886 11.000 18.757 11.763 14.187 M. 5932001 19 6.835 8.886 15.221 9.751 11.763 52.4562002 20 5.250 6.835 12.703 8.084 9.751 42.6232003 21 4.154 5.250 10.616 6.701 8.084 34.8052004 22 3.286 4.154 8.886 6.701 23.0272005 23 2.600 3.286 7.452 13.3382006 24 2.600 6.263 8.8632007 25 5.328 5.3282008 26 4.417 4.4i72009 272010 282011 29
2012 302013 312014 32 ‘2015 33 “2016 34
,Peak Oi 1 Production = 436,000 b / d .
Source: Oames & Moore
* Number i n Parentheses is that of the ori gf nal table which has been revised
E-41
●
●
●
●
●
●
●o
TABLE E-9 (7-13) ●
MEDIUM FIND SCENARIO PRODUCTION BY YEAR FOR INDIVIDUAL FIELDS AND TOTALNON-ASSOCIATED GAS
PRODUCTION lN 8CF YEAR BY FIELD SIZE (EICF )Calendar Year After Central Sound
Year Lease Sal e 1300 1000 Totals
1983 11984 “ 21985 31986 41987 5198a 61989 7 26.280 26.2801990 8 63.072 63.0721991 9 84.096 21.024 105.1201992 10 84.096 42.048 126.1441993 11 84.096 63.072 147.1681994 12 84.096 84.096 168.1921995 13 84.096 84.096 168.1921996 14 84.096 84.096 168.1921997 15 84.096 84.096 168.1921998 16 84.096 84.096 168.1921999 17 84.096 84.096 168.1922000 18 84.096 84.096 168.1922001 19 76.846 72.423 149.2692002 20 61.;80 54.122 116.1022003 21 , 49.936 40.521 .90.4772004 22 40.265 30.710 70.5752005 23 32.454 22.672 55.1262006 24 26.157 16.958 43.1152007 25 21.002 12.685 33.7722008 26 16.992 16.9922009 27 13.696 13.6962010 282011 2 92012 302013 3 12014 322015 332016 34
-..,-.-”, . . --- - . . -----reaK tias rrouuctlon = 40U. U MMCFU.
Source: Dames & Noore
● Number i n parentheses is that of the original table which has been revised
E-42
TAtlLE E-10 (8-12)*
LOW FIND SCENARIO PRODUCTION BY YEAR FOR INDIVIDUAL F IELOS AND TOTAL - OIL
1 PRODUCTION IN MMBBL YEAR BY FIELD SIZE (MMBBL)Calendar Year After Central Souncl
Year Lease Sale 200 I 180 Totals
1983 1
1984 2
1985 3
1986 4
1987 5
1988 6
1989 7
1990 8 7.008 7.008 14.016
1991 9 14.016 14.016 28.032
1992 10 21.024 21.024 42.048
1993 11 28.032 28.032 56.064
1994 12 27.D50 26.962 54.012
1995 13 22.401 20.788 43.189
1996 14 17.432 16.028 33.460
1997 15 13.897 12.357 26.254
199$ 16 11.000 9.527 20.527
1999 17 8.886 7.346 16.232
2000 18 6.835 5.663 12.498
2001 19 5.250 4.366 9.616
2002 20 4.154 30366 7.520
2003 21 3.286 2.595 6.881
2004 2 2 2 . 6 0 0 2.600
2005 23
2006 24 ,
2007 25
2008 26
2009 2?
2010 2a
2011 29 ~
2012 30 .
2013 31
2014 42
2015 33
2016 34
●
●
●
●
*
P e a k Oi 1 P r o d u c t ion = 153,600 b/d
Source: Dames & Moore e* Number’ i n parentheses is that of the origi na 1 table which has been revi secl
e
E-43 ●
TA8LE E-11(8-13)*
LOW FIND SCENAR1O PROOUCTION 8Y YEAR FOR INDIVIDUAL FIELDS AND TOTAL
. PRODUCTIO N IN BCF YEAR BY FIELD SIZE (BCF]Calendar Year A f te r
YearCent ra 1 Sound
Lease Sale 200 Totals
i9B3 i1984 2“ .
1985 3
1986 4
1987 5
1988 6
1989 7
1990 8 2 1 . 0 2 4 2 1 . 0 2 4
1991 9 4 2 . 0 4 8 4 2 . 0 4 8
1992 10 6 3 . 0 7 2 6 3 . 0 7 2
1993 11 8 4 . 0 9 6 8 4 . 0 9 6
1994 12 8 4 . 0 9 6 8 4 . 0 9 61995 13 8 4 . 0 9 6 8 4 . 0 9 6
1996 14 8 4 . 0 9 6 8 4 . 0 9 6
1997 15 8 4 . 0 9 6 8 4 . 0 9 61998 1 6 8 4 . 0 9 6 8 4 . 0 9 61999 17 8 4 . 0 9 6 8 4 . 0 9 62000 18 84.096 8 4 . 0 9 6
2001 19 8 4 . 0 9 6 8 4 . 0 9 62002 2 0 6 9 . 6 0 0 6 9 . 6 0 0
2003 21 5 4 . 6 8 0 5 4 . 6 8 02004 22 4 2 . 9 3 3 4 2 . 9 3 32005 23 33.710 3 3 . 7 1 0
2006 2 4 . 2 6 . 4 6 8 2 6 . 4 6 82007 25 2 0 . 7 8 2 2 0 . 7 8 22008 26 1 6 . 3 1 7 16.3172009 27 1 2 . 8 1 2 1 2 . 8 1 22010 28
2011 29
2012 ’ 3 0
2013 31
2014 3 2
2015 33
2016 34
n... 1--- n--> . . . ---- - -** * ..M-LreISK uus rruuuc~lon = <au. * rwwru.
Source: Dames k Noore
● Nutier i n parentheses I S that of the orl ginal table which has been revised
E-44
Location
Inner Sound
Inner Sound
Inner Sound
Cent ra 1 Sound
Central Sound
Outer Sound
Outer Sound
Central Sound
Central Sound
L2Y_2!-
4A!&!&L
500
200
200
500
200
750
250
--
-..
-.
TABLE E-12 (6-II)*
~IELO PRODUCTION SCHEDULE - HIGH FIND SCENARIO
Id Peak Product ionOi 1
(B;; ) (MBQ ) O&o )-.
--
-..
--
--
-.
-.
1.000
1,000
1.200
153.6
7 6 . 8
7 6 . 8
1 5 3 . 6
7 6 . 8
2 3 0 . 4
7 6 . 8
.-
- -
. .
--
--
--
.-
--
--
2 3 0 . 4
2 3 0 . 4
2 3 0 . 4
IProduct ton
Sta r t Up .
9
10
“ 12
7
8
8
9
7
8
10
ar A f t e r L e a s eProduct ionShut Oown
2 8
24
26
26
22
27
2 2
23
24
29
IePeak
P r o d u c t i o n
12-13
13
15
10-11
11
1 2 - 1 3
1 1 - 1 3
1 0 - 1 6
11-17
13-21
Years ofProduct ion
20
15
15
20
15
20
14
17
17
20
Years of production relates to the date of start up trcm tlrst ]nstal~ed platform (multi-platform fields); production shut downoccurs at same time for all platforms in the same field.
“. Source: Oames & M o o r e
* Number parentheses is that of the original table which has been revised
●e
● ● e *’ P * ● ● ● ☛ ●
,.
TABLE E-13 (6-14 )*. .
MAJOR SHORE FACILITIES START UP AND SHUT DOWN DATES - ~FIND SCENARIO
I Year After Lease..SaleFacility ~Start Up Date Shut oOW~ ~ti2 ~
Cape No.me Oil Terminal 7 28
Cape Nome LNG Plant 7 34
For the purposes of manpower estimation start up is assumed to beJanuary 1.
For thepurposes of manpower estimation shut dowfl is to be Llecember 31
Source: Dames & Moore
* Number parentheses is
,
that of the original table yhich has been revised
.
/’.
E-46
TABLE E-14 [7-11)*
FIELD PRODUCTION SCHEOULE - IIEDIUM FINO’ SCENAR IO
\Field Peak Product ion Y e a r A f t e r L e a s e S a l e
Oi 1 Gas Oi 1 P r o d u c t i o n P r o d u c t i o nL o c a t i o n (MM6BL) (BCF) @l%D)
Peak Years of(14BD) Star t Up Shut Oown Prndur* 4n-
1 IInner Sound 20(! --- 76 Q 1 26 10-11 20
Central Sound 250 - -- 7 6 . 8 - - 8 2i 1 0 - 1 2 14
Outer Sound 250 - - 76.8 - - 9 22 1 1 - 1 3 14
Central Sound - - 1 , 3 0 0 - - 2 3 0 . 4 7 27 9 - 1 8 21
Central Sound - - 1,000 .- 230.4 9 25 1 2 - 1 8 17
Y e a r s o f p r o d u c t i o n r e l a t e s t o t h e d a t e o f s t a r t up f rom f i rs t insta l led platfosns ( m u l t i - p l a t f o r m f i e l d s ) ; p r o d u c t i o n s h u t d o w noccurs at same t ime for a l l p lat forms in the same field.
S o u r c e : D a m e s & hloore
* Number in parentheses is that of the original table w h i c h h a s b e e n r e v i s e d
● ● ● ●o
●
TABLE E-15 [7-14)*
MAJOR SHORE FACILITIES START UP AND SHUT DOWN DATES -IIJM FIND SCENARIO
r Year After Lease SaleFacility Start Up Date hut Down Date
Cape Nome Oil Terminal 7 26
Cape Nome LNG Want 7 27I
For the purposes of manpower estimation start up is assumed to beJanuary 1.
For the purposes of manpower estimation shut down is to be December 31.
Source: Dames & Moore
* Number in parentheses
.
is that of the original table which has been revised
E-48
TABLE E-lb ($-l 1] *
FIELD PRODUCTION SCHEDULE - L(?4 FIND SCENARIO
F i e l d P e a k p r o d u c t i o n Year After Lease SaleO i l Oi 1 Prcxiuction Product ion
L o c a t i o n @iBBL) (%) (&:D)Peak Years of
(MOD) S t a r t Up Shut Down Product ion Product ion
Central Sound 200 -- 7 6 . 8 - - 8 2 2 11 15
Central Sound 180 - - 7 6 . 8 - - 8 21 11 14
Central Sound .- 1,200 -- 230.4 8 27 11-19 20
Y e a r s of p r o d u c t i o n r e l a t e s t o t h e d a t e o f s t a r t u p f r o m f i r s t i n s t a l l e d p l a t f o r m ( m u l t i - p l a t f o r m f i e l d s ) ; p r o d u c t i o n s h u t d o w noccurs at same t ime for all p l a t f o r m s .
Source: Dames h Moore
* Number parentheses is that of the original table which has been revised~
.@m
*
TABLE E-17 (8-14)*
MAJOR SHORE FACILITIES STARTUP AND SHUT DOMNDATES -LOW FIND SCENARIO
* Year After Lease Sale Years of;Facility Start Up Date Shut Down Date fl!!.qvation f
Cape Nome Oil Termtna? 8 27 15
ICape Nome LNG Plant 8 32 20
<
For the purposes of manpower estimation start up is assumed to beJanuary 1.
For the purposes of manpower estimation shut down is to be December 31.
Source: Dames & Moore
* Number parentheses is that of the original table which has been revised
E-50
4.-
0
b
id ‘U*J
● ☛ ✎
Gruw,U-?r==ul
.
*
E-51
___
TABLE E-19
,- . ) A N u A 1 i % J U L Y AN(J PEAK M4WOwlfP REWIRENENT<(l*ut4!iER O F PEOPLE)
Jbl./UA~V JUL WYliAu LFTtd
lJEbKOtFSiIuME Otistio#f JAWAUV uFFSHIME ONSWOKF
Llib\E SALEJULY
WvjilE uFFsITF ONS t TE OFFSIlk TOTAL fJNSITE L)FFSXTE tit+ I TE OFFSITF TOTAL MONTH TOTAL
1 Q. 0. 0. 0. . (). ]#)zb. 13M. .26. 10* 3 3 8 . 6 365. -? ~, ● fl * 0. 0. 0 ● 3ti9. 23+. ~3. 12. 6R2*3
b 6H2.Cl. 0. 0. 1). 00 764. 238. 4\. 129 65s ● 6 682.
q’1
wl’+
TABLE E-20
9
. .
yFAti/8cr~v[IY 1 ?? 3
YEARLY
4
I-I*0.
0.o*
[).(3.
s 6 7 t+ 9 in 11
o* 0. . 0. 0. 0. [1. so ●
0. 00 0. 0 . 0 . o* o .
0 . 0. i]* 0. 0. n . lno.0. 0 . 0. 0 . 0 . 1) . n .
O* 6. 6. 0. n. l). 50.0 . 0 . n . 0. 0. 0 . 0.
e ? ● *
1? 13
4 4 8 . 0s448. 0 ,
h96* o .896. 0.
4 4 8 . o*4 4 a . 0.
●
14 ]5
o* 0.0. 0.
400. i).2no. 0.
400. 0.200. 0.
*-
E-54
LLl
.
‘kl)-
.* *.*.*** ● ✎☛☛✎☛☛☛☛ ✎ ✎ ✎ ✎ ✎ ✎ ✎ ✎ ✎ ✎ ✎
●
*
E-55
. . .
9
‘n
.
E-56
,.--P.)-Cw
‘4 =“
. .0 0
(u
c
● ☛
=e
-.
=“ c“‘-&N.-, r- -
. .C4e
.,=0
. e
● ✎
Y*ccrn
*
> ----3, A f f.<k <L.$ h.
-.
J-
E-57
-
>*ua
**.r
E-58
I’(:*r-
-.
● ☛
ec
. .u=
. .L=
..
**
. . . . .
dld
n
. -L
4.1
E-59
*.2.
u.IA.2
E-60
TABLE E-27
I-n
&
w t s.ll JKt
●
] *,4.In].]50.1>5.t><.2.d.r’.
JULY
CIFJS1 TF IIFFSITE
. . . . . . .OIJSWY?F
OWSIIF OFFSTTF
63.11?.1?5.371.*59*376.?M.@tik.?kQ.25\*?n3.?55.?3s.?55.755.255.?55.755*?55,?55.?~$.2*3.?31.?19.?07.195.@-f ●
1>.l%.15.
●
15.37.42.62.103.55 ●
1530230.167.17rJ.17i3.171).J70.]70.17[1.17C.170.]70.]70.I ?L1.
]70.157.164.lb~.15*.)5s.65*
i’.z’..?.
JULY10TAL
S61.lsdl.1750.168+.2oa3.3q33.21200~545.3154.2895.2365.2?09.2?69.,?359.2389.23H9*2389.2389.2389.?3n9.?W+9.2 1 6 6 .1943.1720.1497.1?74.+60 ●
“117.317.317.
. .Oc
=“ 2w n+r-
>
> . .=x==co-.
. .Oc
. .Cao
)- ~ *.t-+--r. r:> ,*:!&-.
IF > 6
..x
a*
E-62
*
. .c<
. .0 0m
N
. .= --
.,==
COGNa)
LLz.- ,.c=
. .==
. .= .-
f.. .==>.
%
.
TABLE E-29
Yf” At-t AFTt KLF. LSE SALE
SUWk$AuY O F NANPUMER RElJuIIwti14FlJISi FOR ALL INCNJSTt+IESONSITE AN13 T(3TAL ~~
TOTAL(M4N-MONII-ISI
OPJSIiURt
4 5 4 .10.59.12>1.465ti.10210.51’32.499110
11)1%3.60(33.~~<,Y.SO%h.Lti?h.4M4(J*4d*0.4~40*
4bf00.
4t!40.*
ibA4fl.
‘4F40.
&&4rl ,
4q&(l ,
bh.1~.
&544,4396.4?-$FJ.4100.17h6.
?1)0.?(JU ●
/no.
TuTAL MONTHLY AVERAGE[NIJMHFR (JF PEOPLE)
(Jrr >Huwt
3 ? 5 .tB4*9 3 9 .7?9.592.
}98701-/02.?~L& ●
Z’l=Ji.?*+?.)+~b.lbf?~.161+7.lfr7.lhrJ7.IM137.ldh7.lt!i-J7.1807.ltln7.1607.lb19.1431).1/42.1 o’i4.fih~.409.
,ino..300..300.
Urdyruut
38.90.105.3ti9.H51.426.416.H&b.501.446.4?2.407.404.404.404.41-J4.404.404.40+.4nk.404*
.39] ●
379.3b7.3 5 4 .3 4 ? *14Q*17.i7.,17.
lOTAL
363.M73.
1 0 4 3 *111’3.14443.2415.211a.]’391 ,3?31.2rt3R.2’347.?nF19.2090.~ll+(J,2?10.?210.2?10.%2’1O*2210.2Z1O.?210.2010,]Pn~.1608.14013.1?07.63q*317.317.317.
1,
.
.-
E-65
t+m
L/Jw- 1mu1-
------ -
*.- d - - -
-----
*. *.9*..* . . . . . . . . . ● . . ...*..===: =. =.w r------- ------4.-I-!’- -?!-!
Ocn.Zscnnrucr crc-3 **t*
u? ----+
. ...46.. . ..**... . . . . . . . . . . .
E-66
. .--- =
. .cc
. .c c
. .c c
>
.
.8=C
. .02
/-.4.
● ✎
✝✝r
\
>
‘-.2
. *--
. .= .:11
. .I.-1= e-.----- ----
. . . .:● ☛
1- =. . . .‘c. .: cr
. . . .t -- 4.C. ,
:.:
,;,-,,,-.~...-\L&-
.
c1●
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*u
.
L.4-..,.3 --- ._. -
E-67
>
l-u.
. .fix?-7
. .c c
● ✎
=0
. .4i4?F-r-e t-.
● ✎
cc
. .cc
nu.
.1
mcm
&
iu
=K
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.-,-Jn
-.--,..\\,-.
. . . . . . . . ... .0..0 O.*...** . . .
. . . . .
.:
●
e!/
E-69.
9
●
APPENDIX F
●
APPENDIX F
THE MARKETING OF NORTON BASIN OIL AND (YQ
(This was conducted separately fran the remainder of the scenario study and
will be incorporated later when review of a draft is complete).
F-1